isabelle: src/HOL/Multivariate_Analysis/Convex_Euclidean

41959 b460124855b8 tuned headers; wenzelm parents: 41413 diff changeset	1	(* Title: HOL/Multivariate_Analysis/Convex_Euclidean_Space.thy
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2	Author: Robert Himmelmann, TU Muenchen
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	3	Author: Bogdan Grechuk, University of Edinburgh
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4	*)
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6	header {* Convex sets, functions and related things. *}
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	7
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	8	theory Convex_Euclidean_Space
44132 0f35a870ecf1 full import paths huffman parents: 44125 diff changeset	9	imports
56189 c4daa97ac57a removed dependencies on theory Ordered_Euclidean_Space immler parents: 56188 diff changeset	10	Topology_Euclidean_Space
44132 0f35a870ecf1 full import paths huffman parents: 44125 diff changeset	11	"~~/src/HOL/Library/Convex"
0f35a870ecf1 full import paths huffman parents: 44125 diff changeset	12	"~~/src/HOL/Library/Set_Algebras"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	13	begin
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	14
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	15
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	16	(* ------------------------------------------------------------------------- *)
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	17	(* To be moved elsewhere *)
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	18	(* ------------------------------------------------------------------------- *)
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	19
44361 75ec83d45303 remove unnecessary euclidean_space class constraints huffman parents: 44349 diff changeset	20	lemma linear_scaleR: "linear (\<lambda>x. scaleR c x)"
53600 8fda7ad57466 make 'linear' into a sublocale of 'bounded_linear'; huffman parents: 53406 diff changeset	21	by (simp add: linear_iff scaleR_add_right)
44361 75ec83d45303 remove unnecessary euclidean_space class constraints huffman parents: 44349 diff changeset	22
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	23	lemma linear_scaleR_left: "linear (\<lambda>r. scaleR r x)"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	24	by (simp add: linear_iff scaleR_add_left)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	25
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	26	lemma injective_scaleR: "c \<noteq> 0 \<Longrightarrow> inj (\<lambda>x::'a::real_vector. scaleR c x)"
44361 75ec83d45303 remove unnecessary euclidean_space class constraints huffman parents: 44349 diff changeset	27	by (simp add: inj_on_def)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	28
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	29	lemma linear_add_cmul:
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	30	assumes "linear f"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	31	shows "f (a \<^sub>R x + b \<^sub>R y) = a \<^sub>R f x + b \<^sub>R f y"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	32	using linear_add[of f] linear_cmul[of f] assms by simp
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	33
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	34	lemma mem_convex_alt:
53406 d4374a69ddff tuned proofs; wenzelm parents: 53374 diff changeset	35	assumes "convex S" "x \<in> S" "y \<in> S" "u \<ge> 0" "v \<ge> 0" "u + v > 0"
d4374a69ddff tuned proofs; wenzelm parents: 53374 diff changeset	36	shows "((u/(u+v)) \<^sub>R x + (v/(u+v)) \<^sub>R y) \<in> S"
53676 476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	37	apply (rule convexD)
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	38	using assms
53676 476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	39	apply (simp_all add: zero_le_divide_iff add_divide_distrib [symmetric])
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	40	done
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	41
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	42	lemma inj_on_image_mem_iff: "inj_on f B \<Longrightarrow> A \<subseteq> B \<Longrightarrow> f a \<in> f`A \<Longrightarrow> a \<in> B \<Longrightarrow> a \<in> A"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	43	by (blast dest: inj_onD)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	44
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	45	lemma independent_injective_on_span_image:
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	46	assumes iS: "independent S"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	47	and lf: "linear f"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	48	and fi: "inj_on f (span S)"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	49	shows "independent (f ` S)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	50	proof -
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	51	{
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	52	fix a
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	53	assume a: "a \<in> S" "f a \<in> span (f ` S - {f a})"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	54	have eq: "f ` S - {f a} = f ` (S - {a})"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	55	using fi a span_inc by (auto simp add: inj_on_def)
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	56	from a have "f a \<in> f ` span (S -{a})"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	57	unfolding eq span_linear_image [OF lf, of "S - {a}"] by blast
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	58	moreover have "span (S - {a}) \<subseteq> span S"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	59	using span_mono[of "S - {a}" S] by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	60	ultimately have "a \<in> span (S - {a})"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	61	using fi a span_inc by (auto simp add: inj_on_def)
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	62	with a(1) iS have False
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	63	by (simp add: dependent_def)
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	64	}
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	65	then show ?thesis
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	66	unfolding dependent_def by blast
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	67	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	68
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	69	lemma dim_image_eq:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	70	fixes f :: "'n::euclidean_space \<Rightarrow> 'm::euclidean_space"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	71	assumes lf: "linear f"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	72	and fi: "inj_on f (span S)"
53406 d4374a69ddff tuned proofs; wenzelm parents: 53374 diff changeset	73	shows "dim (f ` S) = dim (S::'n::euclidean_space set)"
d4374a69ddff tuned proofs; wenzelm parents: 53374 diff changeset	74	proof -
d4374a69ddff tuned proofs; wenzelm parents: 53374 diff changeset	75	obtain B where B: "B \<subseteq> S" "independent B" "S \<subseteq> span B" "card B = dim S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	76	using basis_exists[of S] by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	77	then have "span S = span B"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	78	using span_mono[of B S] span_mono[of S "span B"] span_span[of B] by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	79	then have "independent (f ` B)"
53406 d4374a69ddff tuned proofs; wenzelm parents: 53374 diff changeset	80	using independent_injective_on_span_image[of B f] B assms by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	81	moreover have "card (f ` B) = card B"
53406 d4374a69ddff tuned proofs; wenzelm parents: 53374 diff changeset	82	using assms card_image[of f B] subset_inj_on[of f "span S" B] B span_inc by auto
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	83	moreover have "(f ` B) \<subseteq> (f ` S)"
53406 d4374a69ddff tuned proofs; wenzelm parents: 53374 diff changeset	84	using B by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	85	ultimately have "dim (f ` S) \<ge> dim S"
53406 d4374a69ddff tuned proofs; wenzelm parents: 53374 diff changeset	86	using independent_card_le_dim[of "f ` B" "f ` S"] B by auto
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	87	then show ?thesis
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	88	using dim_image_le[of f S] assms by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	89	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	90
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	91	lemma linear_injective_on_subspace_0:
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	92	assumes lf: "linear f"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	93	and "subspace S"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	94	shows "inj_on f S \<longleftrightarrow> (\<forall>x \<in> S. f x = 0 \<longrightarrow> x = 0)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	95	proof -
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	96	have "inj_on f S \<longleftrightarrow> (\<forall>x \<in> S. \<forall>y \<in> S. f x = f y \<longrightarrow> x = y)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	97	by (simp add: inj_on_def)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	98	also have "\<dots> \<longleftrightarrow> (\<forall>x \<in> S. \<forall>y \<in> S. f x - f y = 0 \<longrightarrow> x - y = 0)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	99	by simp
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	100	also have "\<dots> \<longleftrightarrow> (\<forall>x \<in> S. \<forall>y \<in> S. f (x - y) = 0 \<longrightarrow> x - y = 0)"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	101	by (simp add: linear_sub[OF lf])
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	102	also have "\<dots> \<longleftrightarrow> (\<forall>x \<in> S. f x = 0 \<longrightarrow> x = 0)"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	103	using `subspace S` subspace_def[of S] subspace_sub[of S] by auto
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	104	finally show ?thesis .
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	105	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	106
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	107	lemma subspace_Inter: "\<forall>s \<in> f. subspace s \<Longrightarrow> subspace (Inter f)"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	108	unfolding subspace_def by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	109
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	110	lemma span_eq[simp]: "span s = s \<longleftrightarrow> subspace s"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	111	unfolding span_def by (rule hull_eq) (rule subspace_Inter)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	112
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	113	lemma substdbasis_expansion_unique:
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	114	assumes d: "d \<subseteq> Basis"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	115	shows "(\<Sum>i\<in>d. f i *\<^sub>R i) = (x::'a::euclidean_space) \<longleftrightarrow>
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	116	(\<forall>i\<in>Basis. (i \<in> d \<longrightarrow> f i = x \<bullet> i) \<and> (i \<notin> d \<longrightarrow> x \<bullet> i = 0))"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	117	proof -
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	118	have : "\<And>x a b P. x (if P then a else b) = (if P then x * a else x * b)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	119	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	120	have **: "finite d"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	121	by (auto intro: finite_subset[OF assms])
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	122	have **: "\<And>i. i \<in> Basis \<Longrightarrow> (\<Sum>i\<in>d. f i \<^sub>R i) \<bullet> i = (\<Sum>x\<in>d. if x = i then f x else 0)"
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	123	using d
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	124	by (auto intro!: setsum_cong simp: inner_Basis inner_setsum_left)
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	125	show ?thesis
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	126	unfolding euclidean_eq_iff[where 'a='a] by (auto simp: setsum_delta[OF ] *)
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	127	qed
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	128
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	129	lemma independent_substdbasis: "d \<subseteq> Basis \<Longrightarrow> independent d"
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	130	by (rule independent_mono[OF independent_Basis])
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	131
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	132	lemma dim_cball:
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	133	assumes "e > 0"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	134	shows "dim (cball (0 :: 'n::euclidean_space) e) = DIM('n)"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	135	proof -
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	136	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	137	fix x :: "'n::euclidean_space"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	138	def y \<equiv> "(e / norm x) *\<^sub>R x"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	139	then have "y \<in> cball 0 e"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	140	using cball_def dist_norm[of 0 y] assms by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	141	moreover have : "x = (norm x / e) \<^sub>R y"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	142	using y_def assms by simp
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	143	moreover from * have "x = (norm x/e) *\<^sub>R y"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	144	by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	145	ultimately have "x \<in> span (cball 0 e)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	146	using span_mul[of y "cball 0 e" "norm x/e"] span_inc[of "cball 0 e"] by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	147	}
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	148	then have "span (cball 0 e) = (UNIV :: 'n::euclidean_space set)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	149	by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	150	then show ?thesis
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	151	using dim_span[of "cball (0 :: 'n::euclidean_space) e"] by (auto simp add: dim_UNIV)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	152	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	153
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	154	lemma indep_card_eq_dim_span:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	155	fixes B :: "'n::euclidean_space set"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	156	assumes "independent B"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	157	shows "finite B \<and> card B = dim (span B)"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	158	using assms basis_card_eq_dim[of B "span B"] span_inc by auto
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	159
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	160	lemma setsum_not_0: "setsum f A \<noteq> 0 \<Longrightarrow> \<exists>a \<in> A. f a \<noteq> 0"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	161	by (rule ccontr) auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	162
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	163	lemma translate_inj_on:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	164	fixes A :: "'a::ab_group_add set"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	165	shows "inj_on (\<lambda>x. a + x) A"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	166	unfolding inj_on_def by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	167
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	168	lemma translation_assoc:
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	169	fixes a b :: "'a::ab_group_add"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	170	shows "(\<lambda>x. b + x) ` ((\<lambda>x. a + x) ` S) = (\<lambda>x. (a + b) + x) ` S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	171	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	172
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	173	lemma translation_invert:
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	174	fixes a :: "'a::ab_group_add"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	175	assumes "(\<lambda>x. a + x) ` A = (\<lambda>x. a + x) ` B"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	176	shows "A = B"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	177	proof -
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	178	have "(\<lambda>x. -a + x) ` ((\<lambda>x. a + x) ` A) = (\<lambda>x. - a + x) ` ((\<lambda>x. a + x) ` B)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	179	using assms by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	180	then show ?thesis
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	181	using translation_assoc[of "-a" a A] translation_assoc[of "-a" a B] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	182	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	183
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	184	lemma translation_galois:
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	185	fixes a :: "'a::ab_group_add"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	186	shows "T = ((\<lambda>x. a + x) ` S) \<longleftrightarrow> S = ((\<lambda>x. (- a) + x) ` T)"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	187	using translation_assoc[of "-a" a S]
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	188	apply auto
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	189	using translation_assoc[of a "-a" T]
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	190	apply auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	191	done
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	192
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	193	lemma translation_inverse_subset:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	194	assumes "((\<lambda>x. - a + x) ` V) \<le> (S :: 'n::ab_group_add set)"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	195	shows "V \<le> ((\<lambda>x. a + x) ` S)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	196	proof -
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	197	{
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	198	fix x
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	199	assume "x \<in> V"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	200	then have "x-a \<in> S" using assms by auto
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	201	then have "x \<in> {a + v \|v. v \<in> S}"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	202	apply auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	203	apply (rule exI[of _ "x-a"])
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	204	apply simp
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	205	done
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	206	then have "x \<in> ((\<lambda>x. a+x) ` S)" by auto
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	207	}
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	208	then show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	209	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	210
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	211	lemma basis_to_basis_subspace_isomorphism:
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	212	assumes s: "subspace (S:: ('n::euclidean_space) set)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	213	and t: "subspace (T :: ('m::euclidean_space) set)"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	214	and d: "dim S = dim T"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	215	and B: "B \<subseteq> S" "independent B" "S \<subseteq> span B" "card B = dim S"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	216	and C: "C \<subseteq> T" "independent C" "T \<subseteq> span C" "card C = dim T"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	217	shows "\<exists>f. linear f \<and> f ` B = C \<and> f ` S = T \<and> inj_on f S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	218	proof -
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	219	from B independent_bound have fB: "finite B"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	220	by blast
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	221	from C independent_bound have fC: "finite C"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	222	by blast
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	223	from B(4) C(4) card_le_inj[of B C] d obtain f where
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	224	f: "f ` B \<subseteq> C" "inj_on f B" using `finite B` `finite C` by auto
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	225	from linear_independent_extend[OF B(2)] obtain g where
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	226	g: "linear g" "\<forall>x \<in> B. g x = f x" by blast
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	227	from inj_on_iff_eq_card[OF fB, of f] f(2)
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	228	have "card (f ` B) = card B" by simp
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	229	with B(4) C(4) have ceq: "card (f ` B) = card C" using d
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	230	by simp
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	231	have "g ` B = f ` B" using g(2)
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	232	by (auto simp add: image_iff)
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	233	also have "\<dots> = C" using card_subset_eq[OF fC f(1) ceq] .
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	234	finally have gBC: "g ` B = C" .
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	235	have gi: "inj_on g B" using f(2) g(2)
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	236	by (auto simp add: inj_on_def)
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	237	note g0 = linear_indep_image_lemma[OF g(1) fB, unfolded gBC, OF C(2) gi]
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	238	{
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	239	fix x y
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	240	assume x: "x \<in> S" and y: "y \<in> S" and gxy: "g x = g y"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	241	from B(3) x y have x': "x \<in> span B" and y': "y \<in> span B"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	242	by blast+
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	243	from gxy have th0: "g (x - y) = 0"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	244	by (simp add: linear_sub[OF g(1)])
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	245	have th1: "x - y \<in> span B" using x' y'
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	246	by (metis span_sub)
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	247	have "x = y" using g0[OF th1 th0] by simp
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	248	}
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	249	then have giS: "inj_on g S" unfolding inj_on_def by blast
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	250	from span_subspace[OF B(1,3) s]
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	251	have "g ` S = span (g ` B)"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	252	by (simp add: span_linear_image[OF g(1)])
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	253	also have "\<dots> = span C"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	254	unfolding gBC ..
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	255	also have "\<dots> = T"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	256	using span_subspace[OF C(1,3) t] .
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	257	finally have gS: "g ` S = T" .
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	258	from g(1) gS giS gBC show ?thesis
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	259	by blast
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	260	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	261
44524 04ad69081646 generalize some lemmas huffman parents: 44523 diff changeset	262	lemma closure_bounded_linear_image:
04ad69081646 generalize some lemmas huffman parents: 44523 diff changeset	263	assumes f: "bounded_linear f"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	264	shows "f ` closure S \<subseteq> closure (f ` S)"
44524 04ad69081646 generalize some lemmas huffman parents: 44523 diff changeset	265	using linear_continuous_on [OF f] closed_closure closure_subset
04ad69081646 generalize some lemmas huffman parents: 44523 diff changeset	266	by (rule image_closure_subset)
04ad69081646 generalize some lemmas huffman parents: 44523 diff changeset	267
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	268	lemma closure_linear_image:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	269	fixes f :: "'m::euclidean_space \<Rightarrow> 'n::real_normed_vector"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	270	assumes "linear f"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	271	shows "f ` (closure S) \<le> closure (f ` S)"
44524 04ad69081646 generalize some lemmas huffman parents: 44523 diff changeset	272	using assms unfolding linear_conv_bounded_linear
04ad69081646 generalize some lemmas huffman parents: 44523 diff changeset	273	by (rule closure_bounded_linear_image)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	274
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	275	lemma closure_injective_linear_image:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	276	fixes f :: "'n::euclidean_space \<Rightarrow> 'n::euclidean_space"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	277	assumes "linear f" "inj f"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	278	shows "f ` (closure S) = closure (f ` S)"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	279	proof -
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	280	obtain f' where f': "linear f' \<and> f \<circ> f' = id \<and> f' \<circ> f = id"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	281	using assms linear_injective_isomorphism[of f] isomorphism_expand by auto
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	282	then have "f' ` closure (f ` S) \<le> closure (S)"
56154 f0a927235162 more complete set of lemmas wrt. image and composition haftmann parents: 55929 diff changeset	283	using closure_linear_image[of f' "f ` S"] image_comp[of f' f] by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	284	then have "f ` f' ` closure (f ` S) \<le> f ` closure S" by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	285	then have "closure (f ` S) \<le> f ` closure S"
56154 f0a927235162 more complete set of lemmas wrt. image and composition haftmann parents: 55929 diff changeset	286	using image_comp[of f f' "closure (f ` S)"] f' by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	287	then show ?thesis using closure_linear_image[of f S] assms by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	288	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	289
44524 04ad69081646 generalize some lemmas huffman parents: 44523 diff changeset	290	lemma closure_scaleR:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	291	fixes S :: "'a::real_normed_vector set"
44524 04ad69081646 generalize some lemmas huffman parents: 44523 diff changeset	292	shows "(op \<^sub>R c) ` (closure S) = closure ((op \<^sub>R c) ` S)"
04ad69081646 generalize some lemmas huffman parents: 44523 diff changeset	293	proof
04ad69081646 generalize some lemmas huffman parents: 44523 diff changeset	294	show "(op \<^sub>R c) ` (closure S) \<subseteq> closure ((op \<^sub>R c) ` S)"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	295	using bounded_linear_scaleR_right
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	296	by (rule closure_bounded_linear_image)
44524 04ad69081646 generalize some lemmas huffman parents: 44523 diff changeset	297	show "closure ((op \<^sub>R c) ` S) \<subseteq> (op \<^sub>R c) ` (closure S)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	298	by (intro closure_minimal image_mono closure_subset closed_scaling closed_closure)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	299	qed
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	300
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	301	lemma fst_linear: "linear fst"
53600 8fda7ad57466 make 'linear' into a sublocale of 'bounded_linear'; huffman parents: 53406 diff changeset	302	unfolding linear_iff by (simp add: algebra_simps)
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	303
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	304	lemma snd_linear: "linear snd"
53600 8fda7ad57466 make 'linear' into a sublocale of 'bounded_linear'; huffman parents: 53406 diff changeset	305	unfolding linear_iff by (simp add: algebra_simps)
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	306
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	307	lemma fst_snd_linear: "linear (\<lambda>(x,y). x + y)"
53600 8fda7ad57466 make 'linear' into a sublocale of 'bounded_linear'; huffman parents: 53406 diff changeset	308	unfolding linear_iff by (simp add: algebra_simps)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	309
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	310	lemma scaleR_2:
44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	311	fixes x :: "'a::real_vector"
44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	312	shows "scaleR 2 x = x + x"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	313	unfolding one_add_one [symmetric] scaleR_left_distrib by simp
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	314
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	315	lemma vector_choose_size:
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	316	"0 \<le> c \<Longrightarrow> \<exists>x::'a::euclidean_space. norm x = c"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	317	apply (rule exI [where x="c *\<^sub>R (SOME i. i \<in> Basis)"])
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	318	apply (auto simp: SOME_Basis)
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	319	done
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	320
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	321	lemma setsum_delta_notmem:
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	322	assumes "x \<notin> s"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	323	shows "setsum (\<lambda>y. if (y = x) then P x else Q y) s = setsum Q s"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	324	and "setsum (\<lambda>y. if (x = y) then P x else Q y) s = setsum Q s"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	325	and "setsum (\<lambda>y. if (y = x) then P y else Q y) s = setsum Q s"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	326	and "setsum (\<lambda>y. if (x = y) then P y else Q y) s = setsum Q s"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	327	apply (rule_tac [!] setsum_cong2)
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	328	using assms
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	329	apply auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	330	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	331
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	332	lemma setsum_delta'':
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	333	fixes s::"'a::real_vector set"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	334	assumes "finite s"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	335	shows "(\<Sum>x\<in>s. (if y = x then f x else 0) \<^sub>R x) = (if y\<in>s then (f y) \<^sub>R y else 0)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	336	proof -
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	337	have : "\<And>x y. (if y = x then f x else (0::real)) \<^sub>R x = (if x=y then (f x) *\<^sub>R x else 0)"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	338	by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	339	show ?thesis
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	340	unfolding * using setsum_delta[OF assms, of y "\<lambda>x. f x *\<^sub>R x"] by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	341	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	342
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	343	lemma if_smult: "(if P then x else (y::real)) \<^sub>R v = (if P then x \<^sub>R v else y *\<^sub>R v)"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	344	by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	345
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	346	lemma dist_triangle_eq:
44361 75ec83d45303 remove unnecessary euclidean_space class constraints huffman parents: 44349 diff changeset	347	fixes x y z :: "'a::real_inner"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	348	shows "dist x z = dist x y + dist y z \<longleftrightarrow>
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	349	norm (x - y) \<^sub>R (y - z) = norm (y - z) \<^sub>R (x - y)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	350	proof -
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	351	have *: "x - y + (y - z) = x - z" by auto
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	352	show ?thesis unfolding dist_norm norm_triangle_eq[of "x - y" "y - z", unfolded *]
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	353	by (auto simp add:norm_minus_commute)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	354	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	355
53406 d4374a69ddff tuned proofs; wenzelm parents: 53374 diff changeset	356	lemma norm_minus_eqI: "x = - y \<Longrightarrow> norm x = norm y" by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	357
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	358	lemma Min_grI:
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	359	assumes "finite A" "A \<noteq> {}" "\<forall>a\<in>A. x < a"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	360	shows "x < Min A"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	361	unfolding Min_gr_iff[OF assms(1,2)] using assms(3) by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	362
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	363	lemma norm_lt: "norm x < norm y \<longleftrightarrow> inner x x < inner y y"
44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	364	unfolding norm_eq_sqrt_inner by simp
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	365
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	366	lemma norm_le: "norm x \<le> norm y \<longleftrightarrow> inner x x \<le> inner y y"
44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	367	unfolding norm_eq_sqrt_inner by simp
44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	368
44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	369
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	370	subsection {* Affine set and affine hull *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	371
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	372	definition affine :: "'a::real_vector set \<Rightarrow> bool"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	373	where "affine s \<longleftrightarrow> (\<forall>x\<in>s. \<forall>y\<in>s. \<forall>u v. u + v = 1 \<longrightarrow> u \<^sub>R x + v \<^sub>R y \<in> s)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	374
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	375	lemma affine_alt: "affine s \<longleftrightarrow> (\<forall>x\<in>s. \<forall>y\<in>s. \<forall>u::real. (1 - u) \<^sub>R x + u \<^sub>R y \<in> s)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	376	unfolding affine_def by (metis eq_diff_eq')
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	377
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	378	lemma affine_empty[intro]: "affine {}"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	379	unfolding affine_def by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	380
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	381	lemma affine_sing[intro]: "affine {x}"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	382	unfolding affine_alt by (auto simp add: scaleR_left_distrib [symmetric])
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	383
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	384	lemma affine_UNIV[intro]: "affine UNIV"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	385	unfolding affine_def by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	386
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	387	lemma affine_Inter: "(\<forall>s\<in>f. affine s) \<Longrightarrow> affine (\<Inter> f)"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	388	unfolding affine_def by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	389
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	390	lemma affine_Int: "affine s \<Longrightarrow> affine t \<Longrightarrow> affine (s \<inter> t)"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	391	unfolding affine_def by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	392
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	393	lemma affine_affine_hull: "affine(affine hull s)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	394	unfolding hull_def
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	395	using affine_Inter[of "{t. affine t \<and> s \<subseteq> t}"] by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	396
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	397	lemma affine_hull_eq[simp]: "(affine hull s = s) \<longleftrightarrow> affine s"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	398	by (metis affine_affine_hull hull_same)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	399
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	400
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	401	subsubsection {* Some explicit formulations (from Lars Schewe) *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	402
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	403	lemma affine:
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	404	fixes V::"'a::real_vector set"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	405	shows "affine V \<longleftrightarrow>
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	406	(\<forall>s u. finite s \<and> s \<noteq> {} \<and> s \<subseteq> V \<and> setsum u s = 1 \<longrightarrow> (setsum (\<lambda>x. (u x) *\<^sub>R x)) s \<in> V)"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	407	unfolding affine_def
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	408	apply rule
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	409	apply(rule, rule, rule)
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	410	apply(erule conjE)+
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	411	defer
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	412	apply (rule, rule, rule, rule, rule)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	413	proof -
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	414	fix x y u v
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	415	assume as: "x \<in> V" "y \<in> V" "u + v = (1::real)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	416	"\<forall>s u. finite s \<and> s \<noteq> {} \<and> s \<subseteq> V \<and> setsum u s = 1 \<longrightarrow> (\<Sum>x\<in>s. u x *\<^sub>R x) \<in> V"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	417	then show "u \<^sub>R x + v \<^sub>R y \<in> V"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	418	apply (cases "x = y")
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	419	using as(4)[THEN spec[where x="{x,y}"], THEN spec[where x="\<lambda>w. if w = x then u else v"]]
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	420	and as(1-3)
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	421	apply (auto simp add: scaleR_left_distrib[symmetric])
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	422	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	423	next
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	424	fix s u
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	425	assume as: "\<forall>x\<in>V. \<forall>y\<in>V. \<forall>u v. u + v = 1 \<longrightarrow> u \<^sub>R x + v \<^sub>R y \<in> V"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	426	"finite s" "s \<noteq> {}" "s \<subseteq> V" "setsum u s = (1::real)"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	427	def n \<equiv> "card s"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	428	have "card s = 0 \<or> card s = 1 \<or> card s = 2 \<or> card s > 2" by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	429	then show "(\<Sum>x\<in>s. u x *\<^sub>R x) \<in> V"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	430	proof (auto simp only: disjE)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	431	assume "card s = 2"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	432	then have "card s = Suc (Suc 0)"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	433	by auto
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	434	then obtain a b where "s = {a, b}"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	435	unfolding card_Suc_eq by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	436	then show ?thesis
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	437	using as(1)[THEN bspec[where x=a], THEN bspec[where x=b]] using as(4,5)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	438	by (auto simp add: setsum_clauses(2))
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	439	next
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	440	assume "card s > 2"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	441	then show ?thesis using as and n_def
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	442	proof (induct n arbitrary: u s)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	443	case 0
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	444	then show ?case by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	445	next
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	446	case (Suc n)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	447	fix s :: "'a set" and u :: "'a \<Rightarrow> real"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	448	assume IA:
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	449	"\<And>u s. \<lbrakk>2 < card s; \<forall>x\<in>V. \<forall>y\<in>V. \<forall>u v. u + v = 1 \<longrightarrow> u \<^sub>R x + v \<^sub>R y \<in> V; finite s;
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	450	s \<noteq> {}; s \<subseteq> V; setsum u s = 1; n = card s \<rbrakk> \<Longrightarrow> (\<Sum>x\<in>s. u x *\<^sub>R x) \<in> V"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	451	and as:
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	452	"Suc n = card s" "2 < card s" "\<forall>x\<in>V. \<forall>y\<in>V. \<forall>u v. u + v = 1 \<longrightarrow> u \<^sub>R x + v \<^sub>R y \<in> V"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	453	"finite s" "s \<noteq> {}" "s \<subseteq> V" "setsum u s = 1"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	454	have "\<exists>x\<in>s. u x \<noteq> 1"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	455	proof (rule ccontr)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	456	assume "\<not> ?thesis"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	457	then have "setsum u s = real_of_nat (card s)"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	458	unfolding card_eq_setsum by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	459	then show False
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	460	using as(7) and `card s > 2`
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	461	by (metis One_nat_def less_Suc0 Zero_not_Suc of_nat_1 of_nat_eq_iff numeral_2_eq_2)
45498 2dc373f1867a avoid numeral-representation-specific rules in metis proof huffman parents: 45051 diff changeset	462	qed
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	463	then obtain x where x:"x \<in> s" "u x \<noteq> 1" by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	464
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	465	have c: "card (s - {x}) = card s - 1"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	466	apply (rule card_Diff_singleton)
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	467	using `x\<in>s` as(4)
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	468	apply auto
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	469	done
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	470	have *: "s = insert x (s - {x})" "finite (s - {x})"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	471	using `x\<in>s` and as(4) by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	472	have **: "setsum u (s - {x}) = 1 - u x"
49530 7faf67b411b4 tuned; wenzelm parents: 49529 diff changeset	473	using setsum_clauses(2)[OF (2), of u x, unfolded (1)[symmetric] as(7)] by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	474	have **: "inverse (1 - u x) setsum u (s - {x}) = 1"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	475	unfolding ** using `u x \<noteq> 1` by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	476	have "(\<Sum>xa\<in>s - {x}. (inverse (1 - u x) * u xa) *\<^sub>R xa) \<in> V"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	477	proof (cases "card (s - {x}) > 2")
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	478	case True
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	479	then have "s - {x} \<noteq> {}" "card (s - {x}) = n"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	480	unfolding c and as(1)[symmetric]
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	481	proof (rule_tac ccontr)
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	482	assume "\<not> s - {x} \<noteq> {}"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	483	then have "card (s - {x}) = 0" unfolding card_0_eq[OF *(2)] by simp
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	484	then show False using True by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	485	qed auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	486	then show ?thesis
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	487	apply (rule_tac IA[of "s - {x}" "\<lambda>y. (inverse (1 - u x) * u y)"])
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	488	unfolding setsum_right_distrib[symmetric]
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	489	using as and *** and True
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	490	apply auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	491	done
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	492	next
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	493	case False
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	494	then have "card (s - {x}) = Suc (Suc 0)"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	495	using as(2) and c by auto
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	496	then obtain a b where "(s - {x}) = {a, b}" "a\<noteq>b"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	497	unfolding card_Suc_eq by auto
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	498	then show ?thesis
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	499	using as(3)[THEN bspec[where x=a], THEN bspec[where x=b]]
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	500	using *** *(2) and `s \<subseteq> V`
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	501	unfolding setsum_right_distrib
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	502	by (auto simp add: setsum_clauses(2))
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	503	qed
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	504	then have "u x + (1 - u x) = 1 \<Longrightarrow>
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	505	u x \<^sub>R x + (1 - u x) \<^sub>R ((\<Sum>xa\<in>s - {x}. u xa *\<^sub>R xa) /\<^sub>R (1 - u x)) \<in> V"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	506	apply -
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	507	apply (rule as(3)[rule_format])
51524 7cb5ac44ca9e rename RealVector.thy to Real_Vector_Spaces.thy hoelzl parents: 51480 diff changeset	508	unfolding Real_Vector_Spaces.scaleR_right.setsum
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	509	using x(1) as(6)
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	510	apply auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	511	done
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	512	then show "(\<Sum>x\<in>s. u x *\<^sub>R x) \<in> V"
49530 7faf67b411b4 tuned; wenzelm parents: 49529 diff changeset	513	unfolding scaleR_scaleR[symmetric] and scaleR_right.setsum [symmetric]
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	514	apply (subst *)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	515	unfolding setsum_clauses(2)[OF *(2)]
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	516	using `u x \<noteq> 1`
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	517	apply auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	518	done
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	519	qed
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	520	next
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	521	assume "card s = 1"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	522	then obtain a where "s={a}"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	523	by (auto simp add: card_Suc_eq)
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	524	then show ?thesis
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	525	using as(4,5) by simp
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	526	qed (insert `s\<noteq>{}` `finite s`, auto)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	527	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	528
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	529	lemma affine_hull_explicit:
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	530	"affine hull p =
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	531	{y. \<exists>s u. finite s \<and> s \<noteq> {} \<and> s \<subseteq> p \<and> setsum u s = 1 \<and> setsum (\<lambda>v. (u v) *\<^sub>R v) s = y}"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	532	apply (rule hull_unique)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	533	apply (subst subset_eq)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	534	prefer 3
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	535	apply rule
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	536	unfolding mem_Collect_eq
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	537	apply (erule exE)+
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	538	apply (erule conjE)+
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	539	prefer 2
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	540	apply rule
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	541	proof -
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	542	fix x
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	543	assume "x\<in>p"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	544	then show "\<exists>s u. finite s \<and> s \<noteq> {} \<and> s \<subseteq> p \<and> setsum u s = 1 \<and> (\<Sum>v\<in>s. u v *\<^sub>R v) = x"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	545	apply (rule_tac x="{x}" in exI)
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	546	apply (rule_tac x="\<lambda>x. 1" in exI)
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	547	apply auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	548	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	549	next
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	550	fix t x s u
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	551	assume as: "p \<subseteq> t" "affine t" "finite s" "s \<noteq> {}"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	552	"s \<subseteq> p" "setsum u s = 1" "(\<Sum>v\<in>s. u v *\<^sub>R v) = x"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	553	then show "x \<in> t"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	554	using as(2)[unfolded affine, THEN spec[where x=s], THEN spec[where x=u]]
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	555	by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	556	next
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	557	show "affine {y. \<exists>s u. finite s \<and> s \<noteq> {} \<and> s \<subseteq> p \<and> setsum u s = 1 \<and> (\<Sum>v\<in>s. u v *\<^sub>R v) = y}"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	558	unfolding affine_def
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	559	apply (rule, rule, rule, rule, rule)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	560	unfolding mem_Collect_eq
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	561	proof -
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	562	fix u v :: real
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	563	assume uv: "u + v = 1"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	564	fix x
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	565	assume "\<exists>s u. finite s \<and> s \<noteq> {} \<and> s \<subseteq> p \<and> setsum u s = 1 \<and> (\<Sum>v\<in>s. u v *\<^sub>R v) = x"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	566	then obtain sx ux where
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	567	x: "finite sx" "sx \<noteq> {}" "sx \<subseteq> p" "setsum ux sx = 1" "(\<Sum>v\<in>sx. ux v *\<^sub>R v) = x"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	568	by auto
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	569	fix y
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	570	assume "\<exists>s u. finite s \<and> s \<noteq> {} \<and> s \<subseteq> p \<and> setsum u s = 1 \<and> (\<Sum>v\<in>s. u v *\<^sub>R v) = y"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	571	then obtain sy uy where
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	572	y: "finite sy" "sy \<noteq> {}" "sy \<subseteq> p" "setsum uy sy = 1" "(\<Sum>v\<in>sy. uy v *\<^sub>R v) = y" by auto
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	573	have xy: "finite (sx \<union> sy)"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	574	using x(1) y(1) by auto
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	575	have **: "(sx \<union> sy) \<inter> sx = sx" "(sx \<union> sy) \<inter> sy = sy"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	576	by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	577	show "\<exists>s ua. finite s \<and> s \<noteq> {} \<and> s \<subseteq> p \<and>
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	578	setsum ua s = 1 \<and> (\<Sum>v\<in>s. ua v \<^sub>R v) = u \<^sub>R x + v *\<^sub>R y"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	579	apply (rule_tac x="sx \<union> sy" in exI)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	580	apply (rule_tac x="\<lambda>a. (if a\<in>sx then u * ux a else 0) + (if a\<in>sy then v * uy a else 0)" in exI)
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	581	unfolding scaleR_left_distrib setsum_addf if_smult scaleR_zero_left
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	582	** setsum_restrict_set[OF xy, symmetric]
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	583	unfolding scaleR_scaleR[symmetric] Real_Vector_Spaces.scaleR_right.setsum [symmetric]
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	584	and setsum_right_distrib[symmetric]
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	585	unfolding x y
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	586	using x(1-3) y(1-3) uv
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	587	apply simp
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	588	done
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	589	qed
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	590	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	591
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	592	lemma affine_hull_finite:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	593	assumes "finite s"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	594	shows "affine hull s = {y. \<exists>u. setsum u s = 1 \<and> setsum (\<lambda>v. u v *\<^sub>R v) s = y}"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	595	unfolding affine_hull_explicit and set_eq_iff and mem_Collect_eq
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	596	apply (rule, rule)
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	597	apply (erule exE)+
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	598	apply (erule conjE)+
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	599	defer
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	600	apply (erule exE)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	601	apply (erule conjE)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	602	proof -
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	603	fix x u
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	604	assume "setsum u s = 1" "(\<Sum>v\<in>s. u v *\<^sub>R v) = x"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	605	then show "\<exists>sa u. finite sa \<and>
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	606	\<not> (\<forall>x. (x \<in> sa) = (x \<in> {})) \<and> sa \<subseteq> s \<and> setsum u sa = 1 \<and> (\<Sum>v\<in>sa. u v *\<^sub>R v) = x"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	607	apply (rule_tac x=s in exI, rule_tac x=u in exI)
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	608	using assms
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	609	apply auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	610	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	611	next
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	612	fix x t u
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	613	assume "t \<subseteq> s"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	614	then have *: "s \<inter> t = t"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	615	by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	616	assume "finite t" "\<not> (\<forall>x. (x \<in> t) = (x \<in> {}))" "setsum u t = 1" "(\<Sum>v\<in>t. u v *\<^sub>R v) = x"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	617	then show "\<exists>u. setsum u s = 1 \<and> (\<Sum>v\<in>s. u v *\<^sub>R v) = x"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	618	apply (rule_tac x="\<lambda>x. if x\<in>t then u x else 0" in exI)
49530 7faf67b411b4 tuned; wenzelm parents: 49529 diff changeset	619	unfolding if_smult scaleR_zero_left and setsum_restrict_set[OF assms, symmetric] and *
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	620	apply auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	621	done
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	622	qed
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	623
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	624
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	625	subsubsection {* Stepping theorems and hence small special cases *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	626
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	627	lemma affine_hull_empty[simp]: "affine hull {} = {}"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	628	by (rule hull_unique) auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	629
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	630	lemma affine_hull_finite_step:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	631	fixes y :: "'a::real_vector"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	632	shows
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	633	"(\<exists>u. setsum u {} = w \<and> setsum (\<lambda>x. u x *\<^sub>R x) {} = y) \<longleftrightarrow> w = 0 \<and> y = 0" (is ?th1)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	634	and
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	635	"finite s \<Longrightarrow>
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	636	(\<exists>u. setsum u (insert a s) = w \<and> setsum (\<lambda>x. u x *\<^sub>R x) (insert a s) = y) \<longleftrightarrow>
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	637	(\<exists>v u. setsum u s = w - v \<and> setsum (\<lambda>x. u x \<^sub>R x) s = y - v \<^sub>R a)" (is "_ \<Longrightarrow> ?lhs = ?rhs")
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	638	proof -
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	639	show ?th1 by simp
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	640	assume fin: "finite s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	641	show "?lhs = ?rhs"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	642	proof
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	643	assume ?lhs
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	644	then obtain u where u: "setsum u (insert a s) = w \<and> (\<Sum>x\<in>insert a s. u x *\<^sub>R x) = y"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	645	by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	646	show ?rhs
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	647	proof (cases "a \<in> s")
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	648	case True
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	649	then have *: "insert a s = s" by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	650	show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	651	using u[unfolded *]
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	652	apply(rule_tac x=0 in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	653	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	654	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	655	next
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	656	case False
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	657	then show ?thesis
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	658	apply (rule_tac x="u a" in exI)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	659	using u and fin
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	660	apply auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	661	done
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	662	qed
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	663	next
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	664	assume ?rhs
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	665	then obtain v u where vu: "setsum u s = w - v" "(\<Sum>x\<in>s. u x \<^sub>R x) = y - v \<^sub>R a"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	666	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	667	have : "\<And>x M. (if x = a then v else M) \<^sub>R x = (if x = a then v \<^sub>R x else M \<^sub>R x)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	668	by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	669	show ?lhs
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	670	proof (cases "a \<in> s")
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	671	case True
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	672	then show ?thesis
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	673	apply (rule_tac x="\<lambda>x. (if x=a then v else 0) + u x" in exI)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	674	unfolding setsum_clauses(2)[OF fin]
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	675	apply simp
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	676	unfolding scaleR_left_distrib and setsum_addf
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	677	unfolding vu and * and scaleR_zero_left
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	678	apply (auto simp add: setsum_delta[OF fin])
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	679	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	680	next
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	681	case False
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	682	then have **:
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	683	"\<And>x. x \<in> s \<Longrightarrow> u x = (if x = a then v else u x)"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	684	"\<And>x. x \<in> s \<Longrightarrow> u x \<^sub>R x = (if x = a then v \<^sub>R x else u x *\<^sub>R x)" by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	685	from False show ?thesis
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	686	apply (rule_tac x="\<lambda>x. if x=a then v else u x" in exI)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	687	unfolding setsum_clauses(2)[OF fin] and * using vu
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	688	using setsum_cong2[of s "\<lambda>x. u x \<^sub>R x" "\<lambda>x. if x = a then v \<^sub>R x else u x \<^sub>R x", OF *(2)]
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	689	using setsum_cong2[of s u "\<lambda>x. if x = a then v else u x", OF **(1)]
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	690	apply auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	691	done
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	692	qed
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	693	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	694	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	695
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	696	lemma affine_hull_2:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	697	fixes a b :: "'a::real_vector"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	698	shows "affine hull {a,b} = {u \<^sub>R a + v \<^sub>R b\| u v. (u + v = 1)}"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	699	(is "?lhs = ?rhs")
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	700	proof -
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	701	have *:
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	702	"\<And>x y z. z = x - y \<longleftrightarrow> y + z = (x::real)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	703	"\<And>x y z. z = x - y \<longleftrightarrow> y + z = (x::'a)" by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	704	have "?lhs = {y. \<exists>u. setsum u {a, b} = 1 \<and> (\<Sum>v\<in>{a, b}. u v *\<^sub>R v) = y}"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	705	using affine_hull_finite[of "{a,b}"] by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	706	also have "\<dots> = {y. \<exists>v u. u b = 1 - v \<and> u b \<^sub>R b = y - v \<^sub>R a}"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	707	by (simp add: affine_hull_finite_step(2)[of "{b}" a])
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	708	also have "\<dots> = ?rhs" unfolding * by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	709	finally show ?thesis by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	710	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	711
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	712	lemma affine_hull_3:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	713	fixes a b c :: "'a::real_vector"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	714	shows "affine hull {a,b,c} = { u \<^sub>R a + v \<^sub>R b + w *\<^sub>R c\| u v w. u + v + w = 1}"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	715	proof -
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	716	have *:
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	717	"\<And>x y z. z = x - y \<longleftrightarrow> y + z = (x::real)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	718	"\<And>x y z. z = x - y \<longleftrightarrow> y + z = (x::'a)" by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	719	show ?thesis
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	720	apply (simp add: affine_hull_finite affine_hull_finite_step)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	721	unfolding *
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	722	apply auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	723	apply (rule_tac x=v in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	724	apply (rule_tac x=va in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	725	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	726	apply (rule_tac x=u in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	727	apply force
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	728	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	729	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	730
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	731	lemma mem_affine:
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	732	assumes "affine S" "x \<in> S" "y \<in> S" "u + v = 1"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	733	shows "u \<^sub>R x + v \<^sub>R y \<in> S"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	734	using assms affine_def[of S] by auto
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	735
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	736	lemma mem_affine_3:
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	737	assumes "affine S" "x \<in> S" "y \<in> S" "z \<in> S" "u + v + w = 1"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	738	shows "u \<^sub>R x + v \<^sub>R y + w *\<^sub>R z \<in> S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	739	proof -
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	740	have "u \<^sub>R x + v \<^sub>R y + w *\<^sub>R z \<in> affine hull {x, y, z}"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	741	using affine_hull_3[of x y z] assms by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	742	moreover
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	743	have "affine hull {x, y, z} \<subseteq> affine hull S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	744	using hull_mono[of "{x, y, z}" "S"] assms by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	745	moreover
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	746	have "affine hull S = S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	747	using assms affine_hull_eq[of S] by auto
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	748	ultimately show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	749	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	750
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	751	lemma mem_affine_3_minus:
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	752	assumes "affine S" "x \<in> S" "y \<in> S" "z \<in> S"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	753	shows "x + v *\<^sub>R (y-z) \<in> S"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	754	using mem_affine_3[of S x y z 1 v "-v"] assms
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	755	by (simp add: algebra_simps)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	756
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	757
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	758	subsubsection {* Some relations between affine hull and subspaces *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	759
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	760	lemma affine_hull_insert_subset_span:
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	761	"affine hull (insert a s) \<subseteq> {a + v\| v . v \<in> span {x - a \| x . x \<in> s}}"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	762	unfolding subset_eq Ball_def
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	763	unfolding affine_hull_explicit span_explicit mem_Collect_eq
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	764	apply (rule, rule)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	765	apply (erule exE)+
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	766	apply (erule conjE)+
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	767	proof -
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	768	fix x t u
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	769	assume as: "finite t" "t \<noteq> {}" "t \<subseteq> insert a s" "setsum u t = 1" "(\<Sum>v\<in>t. u v *\<^sub>R v) = x"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	770	have "(\<lambda>x. x - a) ` (t - {a}) \<subseteq> {x - a \|x. x \<in> s}"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	771	using as(3) by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	772	then show "\<exists>v. x = a + v \<and> (\<exists>S u. finite S \<and> S \<subseteq> {x - a \|x. x \<in> s} \<and> (\<Sum>v\<in>S. u v *\<^sub>R v) = v)"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	773	apply (rule_tac x="x - a" in exI)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	774	apply (rule conjI, simp)
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	775	apply (rule_tac x="(\<lambda>x. x - a) ` (t - {a})" in exI)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	776	apply (rule_tac x="\<lambda>x. u (x + a)" in exI)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	777	apply (rule conjI) using as(1) apply simp
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	778	apply (erule conjI)
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	779	using as(1)
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	780	apply (simp add: setsum_reindex[unfolded inj_on_def] scaleR_right_diff_distrib
49530 7faf67b411b4 tuned; wenzelm parents: 49529 diff changeset	781	setsum_subtractf scaleR_left.setsum[symmetric] setsum_diff1 scaleR_left_diff_distrib)
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	782	unfolding as
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	783	apply simp
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	784	done
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	785	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	786
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	787	lemma affine_hull_insert_span:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	788	assumes "a \<notin> s"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	789	shows "affine hull (insert a s) = {a + v \| v . v \<in> span {x - a \| x. x \<in> s}}"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	790	apply (rule, rule affine_hull_insert_subset_span)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	791	unfolding subset_eq Ball_def
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	792	unfolding affine_hull_explicit and mem_Collect_eq
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	793	proof (rule, rule, erule exE, erule conjE)
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	794	fix y v
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	795	assume "y = a + v" "v \<in> span {x - a \|x. x \<in> s}"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	796	then obtain t u where obt: "finite t" "t \<subseteq> {x - a \|x. x \<in> s}" "a + (\<Sum>v\<in>t. u v *\<^sub>R v) = y"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	797	unfolding span_explicit by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	798	def f \<equiv> "(\<lambda>x. x + a) ` t"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	799	have f: "finite f" "f \<subseteq> s" "(\<Sum>v\<in>f. u (v - a) *\<^sub>R (v - a)) = y - a"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	800	unfolding f_def using obt by (auto simp add: setsum_reindex[unfolded inj_on_def])
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	801	have *: "f \<inter> {a} = {}" "f \<inter> - {a} = f"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	802	using f(2) assms by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	803	show "\<exists>sa u. finite sa \<and> sa \<noteq> {} \<and> sa \<subseteq> insert a s \<and> setsum u sa = 1 \<and> (\<Sum>v\<in>sa. u v *\<^sub>R v) = y"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	804	apply (rule_tac x = "insert a f" in exI)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	805	apply (rule_tac x = "\<lambda>x. if x=a then 1 - setsum (\<lambda>x. u (x - a)) f else u (x - a)" in exI)
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	806	using assms and f
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	807	unfolding setsum_clauses(2)[OF f(1)] and if_smult
35577 43b93e294522 Generalized setsum_cases hoelzl parents: 35542 diff changeset	808	unfolding setsum_cases[OF f(1), of "\<lambda>x. x = a"]
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	809	apply (auto simp add: setsum_subtractf scaleR_left.setsum algebra_simps *)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	810	done
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	811	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	812
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	813	lemma affine_hull_span:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	814	assumes "a \<in> s"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	815	shows "affine hull s = {a + v \| v. v \<in> span {x - a \| x. x \<in> s - {a}}}"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	816	using affine_hull_insert_span[of a "s - {a}", unfolded insert_Diff[OF assms]] by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	817
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	818
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	819	subsubsection {* Parallel affine sets *}
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	820
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	821	definition affine_parallel :: "'a::real_vector set \<Rightarrow> 'a::real_vector set \<Rightarrow> bool"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	822	where "affine_parallel S T \<longleftrightarrow> (\<exists>a. T = (\<lambda>x. a + x) ` S)"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	823
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	824	lemma affine_parallel_expl_aux:
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	825	fixes S T :: "'a::real_vector set"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	826	assumes "\<forall>x. x \<in> S \<longleftrightarrow> a + x \<in> T"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	827	shows "T = (\<lambda>x. a + x) ` S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	828	proof -
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	829	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	830	fix x
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	831	assume "x \<in> T"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	832	then have "( - a) + x \<in> S"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	833	using assms by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	834	then have "x \<in> ((\<lambda>x. a + x) ` S)"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	835	using imageI[of "-a+x" S "(\<lambda>x. a+x)"] by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	836	}
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	837	moreover have "T \<ge> (\<lambda>x. a + x) ` S"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	838	using assms by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	839	ultimately show ?thesis by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	840	qed
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	841
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	842	lemma affine_parallel_expl: "affine_parallel S T \<longleftrightarrow> (\<exists>a. \<forall>x. x \<in> S \<longleftrightarrow> a + x \<in> T)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	843	unfolding affine_parallel_def
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	844	using affine_parallel_expl_aux[of S _ T] by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	845
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	846	lemma affine_parallel_reflex: "affine_parallel S S"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	847	unfolding affine_parallel_def
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	848	apply (rule exI[of _ "0"])
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	849	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	850	done
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	851
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	852	lemma affine_parallel_commut:
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	853	assumes "affine_parallel A B"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	854	shows "affine_parallel B A"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	855	proof -
54230 b1d955791529 more simplification rules on unary and binary minus haftmann parents: 53676 diff changeset	856	from assms obtain a where B: "B = (\<lambda>x. a + x) ` A"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	857	unfolding affine_parallel_def by auto
54230 b1d955791529 more simplification rules on unary and binary minus haftmann parents: 53676 diff changeset	858	have [simp]: "(\<lambda>x. x - a) = plus (- a)" by (simp add: fun_eq_iff)
b1d955791529 more simplification rules on unary and binary minus haftmann parents: 53676 diff changeset	859	from B show ?thesis
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	860	using translation_galois [of B a A]
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	861	unfolding affine_parallel_def by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	862	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	863
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	864	lemma affine_parallel_assoc:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	865	assumes "affine_parallel A B"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	866	and "affine_parallel B C"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	867	shows "affine_parallel A C"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	868	proof -
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	869	from assms obtain ab where "B = (\<lambda>x. ab + x) ` A"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	870	unfolding affine_parallel_def by auto
8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	871	moreover
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	872	from assms obtain bc where "C = (\<lambda>x. bc + x) ` B"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	873	unfolding affine_parallel_def by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	874	ultimately show ?thesis
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	875	using translation_assoc[of bc ab A] unfolding affine_parallel_def by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	876	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	877
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	878	lemma affine_translation_aux:
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	879	fixes a :: "'a::real_vector"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	880	assumes "affine ((\<lambda>x. a + x) ` S)"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	881	shows "affine S"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	882	proof -
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	883	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	884	fix x y u v
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	885	assume xy: "x \<in> S" "y \<in> S" "(u :: real) + v = 1"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	886	then have "(a + x) \<in> ((\<lambda>x. a + x) ` S)" "(a + y) \<in> ((\<lambda>x. a + x) ` S)"
e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	887	by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	888	then have h1: "u \<^sub>R (a + x) + v \<^sub>R (a + y) \<in> (\<lambda>x. a + x) ` S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	889	using xy assms unfolding affine_def by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	890	have "u \<^sub>R (a + x) + v \<^sub>R (a + y) = (u + v) \<^sub>R a + (u \<^sub>R x + v *\<^sub>R y)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	891	by (simp add: algebra_simps)
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	892	also have "\<dots> = a + (u \<^sub>R x + v \<^sub>R y)"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	893	using `u + v = 1` by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	894	ultimately have "a + (u \<^sub>R x + v \<^sub>R y) \<in> (\<lambda>x. a + x) ` S"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	895	using h1 by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	896	then have "u \<^sub>R x + v \<^sub>R y : S" by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	897	}
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	898	then show ?thesis unfolding affine_def by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	899	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	900
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	901	lemma affine_translation:
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	902	fixes a :: "'a::real_vector"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	903	shows "affine S \<longleftrightarrow> affine ((\<lambda>x. a + x) ` S)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	904	proof -
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	905	have "affine S \<Longrightarrow> affine ((\<lambda>x. a + x) ` S)"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	906	using affine_translation_aux[of "-a" "((\<lambda>x. a + x) ` S)"]
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	907	using translation_assoc[of "-a" a S] by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	908	then show ?thesis using affine_translation_aux by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	909	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	910
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	911	lemma parallel_is_affine:
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	912	fixes S T :: "'a::real_vector set"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	913	assumes "affine S" "affine_parallel S T"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	914	shows "affine T"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	915	proof -
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	916	from assms obtain a where "T = (\<lambda>x. a + x) ` S"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	917	unfolding affine_parallel_def by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	918	then show ?thesis
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	919	using affine_translation assms by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	920	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	921
44361 75ec83d45303 remove unnecessary euclidean_space class constraints huffman parents: 44349 diff changeset	922	lemma subspace_imp_affine: "subspace s \<Longrightarrow> affine s"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	923	unfolding subspace_def affine_def by auto
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	924
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	925
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	926	subsubsection {* Subspace parallel to an affine set *}
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	927
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	928	lemma subspace_affine: "subspace S \<longleftrightarrow> affine S \<and> 0 \<in> S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	929	proof -
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	930	have h0: "subspace S \<Longrightarrow> affine S \<and> 0 \<in> S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	931	using subspace_imp_affine[of S] subspace_0 by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	932	{
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	933	assume assm: "affine S \<and> 0 \<in> S"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	934	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	935	fix c :: real
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	936	fix x
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	937	assume x: "x \<in> S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	938	have "c \<^sub>R x = (1-c) \<^sub>R 0 + c *\<^sub>R x" by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	939	moreover
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	940	have "(1 - c) \<^sub>R 0 + c \<^sub>R x \<in> S"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	941	using affine_alt[of S] assm x by auto
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	942	ultimately have "c *\<^sub>R x \<in> S" by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	943	}
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	944	then have h1: "\<forall>c. \<forall>x \<in> S. c *\<^sub>R x \<in> S" by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	945
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	946	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	947	fix x y
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	948	assume xy: "x \<in> S" "y \<in> S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	949	def u == "(1 :: real)/2"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	950	have "(1/2) \<^sub>R (x+y) = (1/2) \<^sub>R (x+y)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	951	by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	952	moreover
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	953	have "(1/2) \<^sub>R (x+y)=(1/2) \<^sub>R x + (1-(1/2)) *\<^sub>R y"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	954	by (simp add: algebra_simps)
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	955	moreover
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	956	have "(1 - u) \<^sub>R x + u \<^sub>R y \<in> S"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	957	using affine_alt[of S] assm xy by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	958	ultimately
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	959	have "(1/2) *\<^sub>R (x+y) \<in> S"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	960	using u_def by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	961	moreover
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	962	have "x + y = 2 \<^sub>R ((1/2) \<^sub>R (x+y))"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	963	by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	964	ultimately
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	965	have "x + y \<in> S"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	966	using h1[rule_format, of "(1/2) *\<^sub>R (x+y)" "2"] by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	967	}
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	968	then have "\<forall>x \<in> S. \<forall>y \<in> S. x + y \<in> S"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	969	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	970	then have "subspace S"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	971	using h1 assm unfolding subspace_def by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	972	}
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	973	then show ?thesis using h0 by metis
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	974	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	975
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	976	lemma affine_diffs_subspace:
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	977	assumes "affine S" "a \<in> S"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	978	shows "subspace ((\<lambda>x. (-a)+x) ` S)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	979	proof -
54230 b1d955791529 more simplification rules on unary and binary minus haftmann parents: 53676 diff changeset	980	have [simp]: "(\<lambda>x. x - a) = plus (- a)" by (simp add: fun_eq_iff)
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	981	have "affine ((\<lambda>x. (-a)+x) ` S)"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	982	using affine_translation assms by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	983	moreover have "0 : ((\<lambda>x. (-a)+x) ` S)"
53333 e9dba6602a84 tuned proofs; wenzelm parents: 53302 diff changeset	984	using assms exI[of "(\<lambda>x. x\<in>S \<and> -a+x = 0)" a] by auto
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	985	ultimately show ?thesis using subspace_affine by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	986	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	987
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	988	lemma parallel_subspace_explicit:
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	989	assumes "affine S"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	990	and "a \<in> S"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	991	assumes "L \<equiv> {y. \<exists>x \<in> S. (-a) + x = y}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	992	shows "subspace L \<and> affine_parallel S L"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	993	proof -
54230 b1d955791529 more simplification rules on unary and binary minus haftmann parents: 53676 diff changeset	994	from assms have "L = plus (- a) ` S" by auto
b1d955791529 more simplification rules on unary and binary minus haftmann parents: 53676 diff changeset	995	then have par: "affine_parallel S L"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	996	unfolding affine_parallel_def ..
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	997	then have "affine L" using assms parallel_is_affine by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	998	moreover have "0 \<in> L"
54230 b1d955791529 more simplification rules on unary and binary minus haftmann parents: 53676 diff changeset	999	using assms by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1000	ultimately show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1001	using subspace_affine par by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1002	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1003
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1004	lemma parallel_subspace_aux:
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1005	assumes "subspace A"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1006	and "subspace B"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1007	and "affine_parallel A B"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1008	shows "A \<supseteq> B"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1009	proof -
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	1010	from assms obtain a where a: "\<forall>x. x \<in> A \<longleftrightarrow> a + x \<in> B"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1011	using affine_parallel_expl[of A B] by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1012	then have "-a \<in> A"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1013	using assms subspace_0[of B] by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1014	then have "a \<in> A"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1015	using assms subspace_neg[of A "-a"] by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1016	then show ?thesis
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	1017	using assms a unfolding subspace_def by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1018	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1019
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1020	lemma parallel_subspace:
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1021	assumes "subspace A"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1022	and "subspace B"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1023	and "affine_parallel A B"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1024	shows "A = B"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1025	proof
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1026	show "A \<supseteq> B"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1027	using assms parallel_subspace_aux by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1028	show "A \<subseteq> B"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1029	using assms parallel_subspace_aux[of B A] affine_parallel_commut by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1030	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1031
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1032	lemma affine_parallel_subspace:
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1033	assumes "affine S" "S \<noteq> {}"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1034	shows "\<exists>!L. subspace L \<and> affine_parallel S L"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1035	proof -
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1036	have ex: "\<exists>L. subspace L \<and> affine_parallel S L"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	1037	using assms parallel_subspace_explicit by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1038	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1039	fix L1 L2
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1040	assume ass: "subspace L1 \<and> affine_parallel S L1" "subspace L2 \<and> affine_parallel S L2"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1041	then have "affine_parallel L1 L2"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1042	using affine_parallel_commut[of S L1] affine_parallel_assoc[of L1 S L2] by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1043	then have "L1 = L2"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1044	using ass parallel_subspace by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1045	}
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1046	then show ?thesis using ex by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1047	qed
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1048
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1049
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	1050	subsection {* Cones *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1051
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1052	definition cone :: "'a::real_vector set \<Rightarrow> bool"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1053	where "cone s \<longleftrightarrow> (\<forall>x\<in>s. \<forall>c\<ge>0. c *\<^sub>R x \<in> s)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1054
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1055	lemma cone_empty[intro, simp]: "cone {}"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1056	unfolding cone_def by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1057
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1058	lemma cone_univ[intro, simp]: "cone UNIV"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1059	unfolding cone_def by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1060
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1061	lemma cone_Inter[intro]: "\<forall>s\<in>f. cone s \<Longrightarrow> cone (\<Inter>f)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1062	unfolding cone_def by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1063
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1064
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	1065	subsubsection {* Conic hull *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1066
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1067	lemma cone_cone_hull: "cone (cone hull s)"
44170 510ac30f44c0 make Multivariate_Analysis work with separate set type huffman parents: 44142 diff changeset	1068	unfolding hull_def by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1069
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1070	lemma cone_hull_eq: "cone hull s = s \<longleftrightarrow> cone s"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1071	apply (rule hull_eq)
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1072	using cone_Inter
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1073	unfolding subset_eq
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1074	apply auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1075	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1076
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1077	lemma mem_cone:
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1078	assumes "cone S" "x \<in> S" "c \<ge> 0"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1079	shows "c *\<^sub>R x : S"
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1080	using assms cone_def[of S] by auto
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1081
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1082	lemma cone_contains_0:
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1083	assumes "cone S"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1084	shows "S \<noteq> {} \<longleftrightarrow> 0 \<in> S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1085	proof -
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1086	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1087	assume "S \<noteq> {}"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1088	then obtain a where "a \<in> S" by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1089	then have "0 \<in> S"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1090	using assms mem_cone[of S a 0] by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1091	}
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1092	then show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1093	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1094
44361 75ec83d45303 remove unnecessary euclidean_space class constraints huffman parents: 44349 diff changeset	1095	lemma cone_0: "cone {0}"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1096	unfolding cone_def by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1097
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1098	lemma cone_Union[intro]: "(\<forall>s\<in>f. cone s) \<longrightarrow> cone (Union f)"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1099	unfolding cone_def by blast
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1100
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1101	lemma cone_iff:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1102	assumes "S \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1103	shows "cone S \<longleftrightarrow> 0 \<in> S \<and> (\<forall>c. c > 0 \<longrightarrow> (op *\<^sub>R c) ` S = S)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1104	proof -
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1105	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1106	assume "cone S"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1107	{
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1108	fix c :: real
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1109	assume "c > 0"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1110	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1111	fix x
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1112	assume "x \<in> S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1113	then have "x \<in> (op *\<^sub>R c) ` S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1114	unfolding image_def
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1115	using `cone S` `c>0` mem_cone[of S x "1/c"]
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	1116	exI[of "(\<lambda>t. t \<in> S \<and> x = c \<^sub>R t)" "(1 / c) \<^sub>R x"]
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1117	by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1118	}
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1119	moreover
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1120	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1121	fix x
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1122	assume "x \<in> (op *\<^sub>R c) ` S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1123	then have "x \<in> S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1124	using `cone S` `c > 0`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1125	unfolding cone_def image_def `c > 0` by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1126	}
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1127	ultimately have "(op *\<^sub>R c) ` S = S" by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1128	}
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1129	then have "0 \<in> S \<and> (\<forall>c. c > 0 \<longrightarrow> (op *\<^sub>R c) ` S = S)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1130	using `cone S` cone_contains_0[of S] assms by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1131	}
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1132	moreover
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1133	{
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1134	assume a: "0 \<in> S \<and> (\<forall>c. c > 0 \<longrightarrow> (op *\<^sub>R c) ` S = S)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1135	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1136	fix x
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1137	assume "x \<in> S"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1138	fix c1 :: real
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1139	assume "c1 \<ge> 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1140	then have "c1 = 0 \<or> c1 > 0" by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1141	then have "c1 *\<^sub>R x \<in> S" using a `x \<in> S` by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1142	}
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1143	then have "cone S" unfolding cone_def by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1144	}
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1145	ultimately show ?thesis by blast
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1146	qed
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1147
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1148	lemma cone_hull_empty: "cone hull {} = {}"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1149	by (metis cone_empty cone_hull_eq)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1150
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1151	lemma cone_hull_empty_iff: "S = {} \<longleftrightarrow> cone hull S = {}"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1152	by (metis bot_least cone_hull_empty hull_subset xtrans(5))
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1153
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1154	lemma cone_hull_contains_0: "S \<noteq> {} \<longleftrightarrow> 0 \<in> cone hull S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1155	using cone_cone_hull[of S] cone_contains_0[of "cone hull S"] cone_hull_empty_iff[of S]
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1156	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1157
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1158	lemma mem_cone_hull:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1159	assumes "x \<in> S" "c \<ge> 0"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1160	shows "c *\<^sub>R x \<in> cone hull S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1161	by (metis assms cone_cone_hull hull_inc mem_cone)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1162
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1163	lemma cone_hull_expl: "cone hull S = {c *\<^sub>R x \| c x. c \<ge> 0 \<and> x \<in> S}"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1164	(is "?lhs = ?rhs")
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1165	proof -
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1166	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1167	fix x
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1168	assume "x \<in> ?rhs"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	1169	then obtain cx :: real and xx where x: "x = cx *\<^sub>R xx" "cx \<ge> 0" "xx \<in> S"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1170	by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1171	fix c :: real
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1172	assume c: "c \<ge> 0"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1173	then have "c \<^sub>R x = (c cx) *\<^sub>R xx"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	1174	using x by (simp add: algebra_simps)
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1175	moreover
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1176	have "c * cx \<ge> 0"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	1177	using c x using mult_nonneg_nonneg by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1178	ultimately
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	1179	have "c *\<^sub>R x \<in> ?rhs" using x by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1180	}
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1181	then have "cone ?rhs"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1182	unfolding cone_def by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1183	then have "?rhs \<in> Collect cone"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1184	unfolding mem_Collect_eq by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1185	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1186	fix x
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1187	assume "x \<in> S"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1188	then have "1 *\<^sub>R x \<in> ?rhs"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	1189	apply auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1190	apply (rule_tac x = 1 in exI)
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1191	apply auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1192	done
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1193	then have "x \<in> ?rhs" by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1194	}
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1195	then have "S \<subseteq> ?rhs" by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1196	then have "?lhs \<subseteq> ?rhs"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1197	using `?rhs \<in> Collect cone` hull_minimal[of S "?rhs" "cone"] by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1198	moreover
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1199	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1200	fix x
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1201	assume "x \<in> ?rhs"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	1202	then obtain cx :: real and xx where x: "x = cx *\<^sub>R xx" "cx \<ge> 0" "xx \<in> S"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1203	by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1204	then have "xx \<in> cone hull S"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1205	using hull_subset[of S] by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1206	then have "x \<in> ?lhs"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	1207	using x cone_cone_hull[of S] cone_def[of "cone hull S"] by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1208	}
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1209	ultimately show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1210	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1211
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1212	lemma cone_closure:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1213	fixes S :: "'a::real_normed_vector set"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1214	assumes "cone S"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1215	shows "cone (closure S)"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1216	proof (cases "S = {}")
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1217	case True
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1218	then show ?thesis by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1219	next
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1220	case False
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1221	then have "0 \<in> S \<and> (\<forall>c. c > 0 \<longrightarrow> op *\<^sub>R c ` S = S)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1222	using cone_iff[of S] assms by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1223	then have "0 \<in> closure S \<and> (\<forall>c. c > 0 \<longrightarrow> op *\<^sub>R c ` closure S = closure S)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1224	using closure_subset by (auto simp add: closure_scaleR)
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1225	then show ?thesis
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1226	using cone_iff[of "closure S"] by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1227	qed
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1228
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1229
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	1230	subsection {* Affine dependence and consequential theorems (from Lars Schewe) *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1231
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1232	definition affine_dependent :: "'a::real_vector set \<Rightarrow> bool"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1233	where "affine_dependent s \<longleftrightarrow> (\<exists>x\<in>s. x \<in> affine hull (s - {x}))"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1234
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1235	lemma affine_dependent_explicit:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1236	"affine_dependent p \<longleftrightarrow>
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1237	(\<exists>s u. finite s \<and> s \<subseteq> p \<and> setsum u s = 0 \<and>
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1238	(\<exists>v\<in>s. u v \<noteq> 0) \<and> setsum (\<lambda>v. u v *\<^sub>R v) s = 0)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1239	unfolding affine_dependent_def affine_hull_explicit mem_Collect_eq
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1240	apply rule
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1241	apply (erule bexE, erule exE, erule exE)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1242	apply (erule conjE)+
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1243	defer
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1244	apply (erule exE, erule exE)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1245	apply (erule conjE)+
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1246	apply (erule bexE)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1247	proof -
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1248	fix x s u
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1249	assume as: "x \<in> p" "finite s" "s \<noteq> {}" "s \<subseteq> p - {x}" "setsum u s = 1" "(\<Sum>v\<in>s. u v *\<^sub>R v) = x"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1250	have "x \<notin> s" using as(1,4) by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1251	show "\<exists>s u. finite s \<and> s \<subseteq> p \<and> setsum u s = 0 \<and> (\<exists>v\<in>s. u v \<noteq> 0) \<and> (\<Sum>v\<in>s. u v *\<^sub>R v) = 0"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1252	apply (rule_tac x="insert x s" in exI, rule_tac x="\<lambda>v. if v = x then - 1 else u v" in exI)
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1253	unfolding if_smult and setsum_clauses(2)[OF as(2)] and setsum_delta_notmem[OF `x\<notin>s`] and as
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1254	using as
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1255	apply auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1256	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1257	next
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1258	fix s u v
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1259	assume as: "finite s" "s \<subseteq> p" "setsum u s = 0" "(\<Sum>v\<in>s. u v *\<^sub>R v) = 0" "v \<in> s" "u v \<noteq> 0"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1260	have "s \<noteq> {v}"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1261	using as(3,6) by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1262	then show "\<exists>x\<in>p. \<exists>s u. finite s \<and> s \<noteq> {} \<and> s \<subseteq> p - {x} \<and> setsum u s = 1 \<and> (\<Sum>v\<in>s. u v *\<^sub>R v) = x"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1263	apply (rule_tac x=v in bexI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1264	apply (rule_tac x="s - {v}" in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1265	apply (rule_tac x="\<lambda>x. - (1 / u v) * u x" in exI)
49530 7faf67b411b4 tuned; wenzelm parents: 49529 diff changeset	1266	unfolding scaleR_scaleR[symmetric] and scaleR_right.setsum [symmetric]
7faf67b411b4 tuned; wenzelm parents: 49529 diff changeset	1267	unfolding setsum_right_distrib[symmetric] and setsum_diff1[OF as(1)]
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1268	using as
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1269	apply auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1270	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1271	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1272
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1273	lemma affine_dependent_explicit_finite:
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1274	fixes s :: "'a::real_vector set"
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1275	assumes "finite s"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1276	shows "affine_dependent s \<longleftrightarrow>
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1277	(\<exists>u. setsum u s = 0 \<and> (\<exists>v\<in>s. u v \<noteq> 0) \<and> setsum (\<lambda>v. u v *\<^sub>R v) s = 0)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1278	(is "?lhs = ?rhs")
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1279	proof
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1280	have : "\<And>vt u v. (if vt then u v else 0) \<^sub>R v = (if vt then (u v) *\<^sub>R v else 0::'a)"
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1281	by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1282	assume ?lhs
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1283	then obtain t u v where
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1284	"finite t" "t \<subseteq> s" "setsum u t = 0" "v\<in>t" "u v \<noteq> 0" "(\<Sum>v\<in>t. u v *\<^sub>R v) = 0"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1285	unfolding affine_dependent_explicit by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1286	then show ?rhs
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1287	apply (rule_tac x="\<lambda>x. if x\<in>t then u x else 0" in exI)
49530 7faf67b411b4 tuned; wenzelm parents: 49529 diff changeset	1288	apply auto unfolding * and setsum_restrict_set[OF assms, symmetric]
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1289	unfolding Int_absorb1[OF `t\<subseteq>s`]
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1290	apply auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1291	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1292	next
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1293	assume ?rhs
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1294	then obtain u v where "setsum u s = 0" "v\<in>s" "u v \<noteq> 0" "(\<Sum>v\<in>s. u v *\<^sub>R v) = 0"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1295	by auto
49529 d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1296	then show ?lhs unfolding affine_dependent_explicit
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1297	using assms by auto
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1298	qed
d523702bdae7 tuned proofs; wenzelm parents: 47445 diff changeset	1299
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1300
44465 fa56622bb7bc move connected_real_lemma to the one place it is used huffman parents: 44457 diff changeset	1301	subsection {* Connectedness of convex sets *}
fa56622bb7bc move connected_real_lemma to the one place it is used huffman parents: 44457 diff changeset	1302
51480 3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1303	lemma connectedD:
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1304	"connected S \<Longrightarrow> open A \<Longrightarrow> open B \<Longrightarrow> S \<subseteq> A \<union> B \<Longrightarrow> A \<inter> B \<inter> S = {} \<Longrightarrow> A \<inter> S = {} \<or> B \<inter> S = {}"
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1305	by (metis connected_def)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1306
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1307	lemma convex_connected:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1308	fixes s :: "'a::real_normed_vector set"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1309	assumes "convex s"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1310	shows "connected s"
51480 3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1311	proof (rule connectedI)
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1312	fix A B
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1313	assume "open A" "open B" "A \<inter> B \<inter> s = {}" "s \<subseteq> A \<union> B"
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1314	moreover
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1315	assume "A \<inter> s \<noteq> {}" "B \<inter> s \<noteq> {}"
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1316	then obtain a b where a: "a \<in> A" "a \<in> s" and b: "b \<in> B" "b \<in> s" by auto
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1317	def f \<equiv> "\<lambda>u. u \<^sub>R a + (1 - u) \<^sub>R b"
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1318	then have "continuous_on {0 .. 1} f"
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1319	by (auto intro!: continuous_on_intros)
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1320	then have "connected (f ` {0 .. 1})"
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1321	by (auto intro!: connected_continuous_image)
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1322	note connectedD[OF this, of A B]
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1323	moreover have "a \<in> A \<inter> f ` {0 .. 1}"
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1324	using a by (auto intro!: image_eqI[of _ _ 1] simp: f_def)
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1325	moreover have "b \<in> B \<inter> f ` {0 .. 1}"
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1326	using b by (auto intro!: image_eqI[of _ _ 0] simp: f_def)
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1327	moreover have "f ` {0 .. 1} \<subseteq> s"
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1328	using `convex s` a b unfolding convex_def f_def by auto
3793c3a11378 move connected to HOL image; used to show intermediate value theorem hoelzl parents: 51475 diff changeset	1329	ultimately show False by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1330	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1331
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	1332	text {* One rather trivial consequence. *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1333
34964 4e8be3c04d37 Replaced vec1 and dest_vec1 by abbreviation. hoelzl parents: 34915 diff changeset	1334	lemma connected_UNIV[intro]: "connected (UNIV :: 'a::real_normed_vector set)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1335	by(simp add: convex_connected convex_UNIV)
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1336
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	1337	text {* Balls, being convex, are connected. *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1338
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	1339	lemma convex_prod:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1340	assumes "\<And>i. i \<in> Basis \<Longrightarrow> convex {x. P i x}"
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	1341	shows "convex {x. \<forall>i\<in>Basis. P i (x\<bullet>i)}"
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	1342	using assms unfolding convex_def
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	1343	by (auto simp: inner_add_left)
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	1344
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	1345	lemma convex_positive_orthant: "convex {x::'a::euclidean_space. (\<forall>i\<in>Basis. 0 \<le> x\<bullet>i)}"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	1346	by (rule convex_prod) (simp add: atLeast_def[symmetric] convex_real_interval)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1347
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1348	lemma convex_local_global_minimum:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1349	fixes s :: "'a::real_normed_vector set"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1350	assumes "e > 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1351	and "convex_on s f"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1352	and "ball x e \<subseteq> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1353	and "\<forall>y\<in>ball x e. f x \<le> f y"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1354	shows "\<forall>y\<in>s. f x \<le> f y"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1355	proof (rule ccontr)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1356	have "x \<in> s" using assms(1,3) by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1357	assume "\<not> ?thesis"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1358	then obtain y where "y\<in>s" and y: "f x > f y" by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1359	then have xy: "0 < dist x y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1360	by (auto simp add: dist_nz[symmetric])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1361
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1362	then obtain u where "0 < u" "u \<le> 1" and u: "u < e / dist x y"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1363	using real_lbound_gt_zero[of 1 "e / dist x y"]
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1364	using xy `e>0` and divide_pos_pos[of e "dist x y"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1365	by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1366	then have "f ((1-u) \<^sub>R x + u \<^sub>R y) \<le> (1-u) * f x + u * f y"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1367	using `x\<in>s` `y\<in>s`
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1368	using assms(2)[unfolded convex_on_def,
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1369	THEN bspec[where x=x], THEN bspec[where x=y], THEN spec[where x="1-u"]]
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1370	by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1371	moreover
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1372	have : "x - ((1 - u) \<^sub>R x + u \<^sub>R y) = u \<^sub>R (x - y)"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1373	by (simp add: algebra_simps)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1374	have "(1 - u) \<^sub>R x + u \<^sub>R y \<in> ball x e"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1375	unfolding mem_ball dist_norm
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1376	unfolding * and norm_scaleR and abs_of_pos[OF `0<u`]
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1377	unfolding dist_norm[symmetric]
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1378	using u
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1379	unfolding pos_less_divide_eq[OF xy]
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1380	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1381	then have "f x \<le> f ((1 - u) \<^sub>R x + u \<^sub>R y)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1382	using assms(4) by auto
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1383	ultimately show False
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1384	using mult_strict_left_mono[OF y `u>0`]
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1385	unfolding left_diff_distrib
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1386	by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1387	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1388
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1389	lemma convex_ball:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1390	fixes x :: "'a::real_normed_vector"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	1391	shows "convex (ball x e)"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1392	proof (auto simp add: convex_def)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1393	fix y z
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1394	assume yz: "dist x y < e" "dist x z < e"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1395	fix u v :: real
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1396	assume uv: "0 \<le> u" "0 \<le> v" "u + v = 1"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1397	have "dist x (u \<^sub>R y + v \<^sub>R z) \<le> u * dist x y + v * dist x z"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1398	using uv yz
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1399	using convex_on_dist [of "ball x e" x, unfolded convex_on_def,
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1400	THEN bspec[where x=y], THEN bspec[where x=z]]
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1401	by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1402	then show "dist x (u \<^sub>R y + v \<^sub>R z) < e"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1403	using convex_bound_lt[OF yz uv] by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1404	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1405
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1406	lemma convex_cball:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1407	fixes x :: "'a::real_normed_vector"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1408	shows "convex (cball x e)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1409	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1410	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1411	fix y z
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1412	assume yz: "dist x y \<le> e" "dist x z \<le> e"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1413	fix u v :: real
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1414	assume uv: "0 \<le> u" "0 \<le> v" "u + v = 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1415	have "dist x (u \<^sub>R y + v \<^sub>R z) \<le> u * dist x y + v * dist x z"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1416	using uv yz
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1417	using convex_on_dist [of "cball x e" x, unfolded convex_on_def,
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1418	THEN bspec[where x=y], THEN bspec[where x=z]]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1419	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1420	then have "dist x (u \<^sub>R y + v \<^sub>R z) \<le> e"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1421	using convex_bound_le[OF yz uv] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1422	}
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1423	then show ?thesis by (auto simp add: convex_def Ball_def)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1424	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1425
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1426	lemma connected_ball:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1427	fixes x :: "'a::real_normed_vector"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1428	shows "connected (ball x e)"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1429	using convex_connected convex_ball by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1430
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1431	lemma connected_cball:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1432	fixes x :: "'a::real_normed_vector"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1433	shows "connected (cball x e)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1434	using convex_connected convex_cball by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1435
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1436
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	1437	subsection {* Convex hull *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1438
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1439	lemma convex_convex_hull: "convex (convex hull s)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1440	unfolding hull_def
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1441	using convex_Inter[of "{t. convex t \<and> s \<subseteq> t}"]
44170 510ac30f44c0 make Multivariate_Analysis work with separate set type huffman parents: 44142 diff changeset	1442	by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1443
34064 eee04bbbae7e avoid dependency on implicit dest rule predicate1D in proofs haftmann parents: 33758 diff changeset	1444	lemma convex_hull_eq: "convex hull s = s \<longleftrightarrow> convex s"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1445	by (metis convex_convex_hull hull_same)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1446
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1447	lemma bounded_convex_hull:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1448	fixes s :: "'a::real_normed_vector set"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1449	assumes "bounded s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1450	shows "bounded (convex hull s)"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1451	proof -
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1452	from assms obtain B where B: "\<forall>x\<in>s. norm x \<le> B"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1453	unfolding bounded_iff by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1454	show ?thesis
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1455	apply (rule bounded_subset[OF bounded_cball, of _ 0 B])
44170 510ac30f44c0 make Multivariate_Analysis work with separate set type huffman parents: 44142 diff changeset	1456	unfolding subset_hull[of convex, OF convex_cball]
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1457	unfolding subset_eq mem_cball dist_norm using B
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1458	apply auto
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1459	done
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1460	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1461
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1462	lemma finite_imp_bounded_convex_hull:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1463	fixes s :: "'a::real_normed_vector set"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1464	shows "finite s \<Longrightarrow> bounded (convex hull s)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1465	using bounded_convex_hull finite_imp_bounded
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1466	by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1467
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1468
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	1469	subsubsection {* Convex hull is "preserved" by a linear function *}
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1470
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1471	lemma convex_hull_linear_image:
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1472	assumes f: "linear f"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1473	shows "f ` (convex hull s) = convex hull (f ` s)"
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1474	proof
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1475	show "convex hull (f ` s) \<subseteq> f ` (convex hull s)"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1476	by (intro hull_minimal image_mono hull_subset convex_linear_image assms convex_convex_hull)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1477	show "f ` (convex hull s) \<subseteq> convex hull (f ` s)"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1478	proof (unfold image_subset_iff_subset_vimage, rule hull_minimal)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1479	show "s \<subseteq> f -` (convex hull (f ` s))"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1480	by (fast intro: hull_inc)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1481	show "convex (f -` (convex hull (f ` s)))"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1482	by (intro convex_linear_vimage [OF f] convex_convex_hull)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1483	qed
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1484	qed
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1485
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1486	lemma in_convex_hull_linear_image:
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1487	assumes "linear f"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1488	and "x \<in> convex hull s"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1489	shows "f x \<in> convex hull (f ` s)"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1490	using convex_hull_linear_image[OF assms(1)] assms(2) by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1491
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1492	lemma convex_hull_Times:
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1493	"convex hull (s \<times> t) = (convex hull s) \<times> (convex hull t)"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1494	proof
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1495	show "convex hull (s \<times> t) \<subseteq> (convex hull s) \<times> (convex hull t)"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1496	by (intro hull_minimal Sigma_mono hull_subset convex_Times convex_convex_hull)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1497	have "\<forall>x\<in>convex hull s. \<forall>y\<in>convex hull t. (x, y) \<in> convex hull (s \<times> t)"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1498	proof (intro hull_induct)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1499	fix x y assume "x \<in> s" and "y \<in> t"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1500	then show "(x, y) \<in> convex hull (s \<times> t)"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1501	by (simp add: hull_inc)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1502	next
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1503	fix x let ?S = "((\<lambda>y. (0, y)) -` (\<lambda>p. (- x, 0) + p) ` (convex hull s \<times> t))"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1504	have "convex ?S"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1505	by (intro convex_linear_vimage convex_translation convex_convex_hull,
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1506	simp add: linear_iff)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1507	also have "?S = {y. (x, y) \<in> convex hull (s \<times> t)}"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1508	by (auto simp add: uminus_add_conv_diff image_def Bex_def)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1509	finally show "convex {y. (x, y) \<in> convex hull (s \<times> t)}" .
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1510	next
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1511	show "convex {x. \<forall>y\<in>convex hull t. (x, y) \<in> convex hull (s \<times> t)}"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1512	proof (unfold Collect_ball_eq, rule convex_INT [rule_format])
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1513	fix y let ?S = "((\<lambda>x. (x, 0)) -` (\<lambda>p. (0, - y) + p) ` (convex hull s \<times> t))"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1514	have "convex ?S"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1515	by (intro convex_linear_vimage convex_translation convex_convex_hull,
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1516	simp add: linear_iff)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1517	also have "?S = {x. (x, y) \<in> convex hull (s \<times> t)}"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1518	by (auto simp add: uminus_add_conv_diff image_def Bex_def)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1519	finally show "convex {x. (x, y) \<in> convex hull (s \<times> t)}" .
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1520	qed
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1521	qed
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1522	then show "(convex hull s) \<times> (convex hull t) \<subseteq> convex hull (s \<times> t)"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1523	unfolding subset_eq split_paired_Ball_Sigma .
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1524	qed
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	1525
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	1526
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	1527	subsubsection {* Stepping theorems for convex hulls of finite sets *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1528
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1529	lemma convex_hull_empty[simp]: "convex hull {} = {}"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1530	by (rule hull_unique) auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1531
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1532	lemma convex_hull_singleton[simp]: "convex hull {a} = {a}"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1533	by (rule hull_unique) auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1534
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1535	lemma convex_hull_insert:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1536	fixes s :: "'a::real_vector set"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1537	assumes "s \<noteq> {}"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1538	shows "convex hull (insert a s) =
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1539	{x. \<exists>u\<ge>0. \<exists>v\<ge>0. \<exists>b. (u + v = 1) \<and> b \<in> (convex hull s) \<and> (x = u \<^sub>R a + v \<^sub>R b)}"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1540	(is "_ = ?hull")
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1541	apply (rule, rule hull_minimal, rule)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1542	unfolding insert_iff
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1543	prefer 3
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1544	apply rule
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1545	proof -
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1546	fix x
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1547	assume x: "x = a \<or> x \<in> s"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1548	then show "x \<in> ?hull"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1549	apply rule
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1550	unfolding mem_Collect_eq
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1551	apply (rule_tac x=1 in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1552	defer
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1553	apply (rule_tac x=0 in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1554	using assms hull_subset[of s convex]
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1555	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1556	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1557	next
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1558	fix x
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1559	assume "x \<in> ?hull"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1560	then obtain u v b where obt: "u\<ge>0" "v\<ge>0" "u + v = 1" "b \<in> convex hull s" "x = u \<^sub>R a + v \<^sub>R b"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1561	by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1562	have "a \<in> convex hull insert a s" "b \<in> convex hull insert a s"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1563	using hull_mono[of s "insert a s" convex] hull_mono[of "{a}" "insert a s" convex] and obt(4)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1564	by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1565	then show "x \<in> convex hull insert a s"
53676 476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	1566	unfolding obt(5) using obt(1-3)
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	1567	by (rule convexD [OF convex_convex_hull])
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1568	next
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1569	show "convex ?hull"
53676 476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	1570	proof (rule convexI)
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1571	fix x y u v
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1572	assume as: "(0::real) \<le> u" "0 \<le> v" "u + v = 1" "x\<in>?hull" "y\<in>?hull"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1573	from as(4) obtain u1 v1 b1 where
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1574	obt1: "u1\<ge>0" "v1\<ge>0" "u1 + v1 = 1" "b1 \<in> convex hull s" "x = u1 \<^sub>R a + v1 \<^sub>R b1"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1575	by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1576	from as(5) obtain u2 v2 b2 where
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1577	obt2: "u2\<ge>0" "v2\<ge>0" "u2 + v2 = 1" "b2 \<in> convex hull s" "y = u2 \<^sub>R a + v2 \<^sub>R b2"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1578	by auto
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1579	have : "\<And>(x::'a) s1 s2. x - s1 \<^sub>R x - s2 \<^sub>R x = ((1::real) - (s1 + s2)) \<^sub>R x"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1580	by (auto simp add: algebra_simps)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1581	have *: "\<exists>b \<in> convex hull s. u \<^sub>R x + v *\<^sub>R y =
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1582	(u * u1) \<^sub>R a + (v u2) \<^sub>R a + (b - (u u1) \<^sub>R b - (v u2) *\<^sub>R b)"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1583	proof (cases "u * v1 + v * v2 = 0")
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1584	case True
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1585	have : "\<And>(x::'a) s1 s2. x - s1 \<^sub>R x - s2 \<^sub>R x = ((1::real) - (s1 + s2)) \<^sub>R x"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1586	by (auto simp add: algebra_simps)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1587	from True have **: "u v1 = 0" "v * v2 = 0"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1588	using mult_nonneg_nonneg[OF `u\<ge>0` `v1\<ge>0`] mult_nonneg_nonneg[OF `v\<ge>0` `v2\<ge>0`]
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1589	by arith+
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1590	then have "u * u1 + v * u2 = 1"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1591	using as(3) obt1(3) obt2(3) by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1592	then show ?thesis
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1593	unfolding obt1(5) obt2(5) *
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1594	using assms hull_subset[of s convex]
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1595	by (auto simp add: *** scaleR_right_distrib)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1596	next
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1597	case False
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1598	have "1 - (u * u1 + v * u2) = (u + v) - (u * u1 + v * u2)"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1599	using as(3) obt1(3) obt2(3) by (auto simp add: field_simps)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1600	also have "\<dots> = u * (v1 + u1 - u1) + v * (v2 + u2 - u2)"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1601	using as(3) obt1(3) obt2(3) by (auto simp add: field_simps)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1602	also have "\<dots> = u * v1 + v * v2"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1603	by simp
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1604	finally have *:"1 - (u u1 + v * u2) = u * v1 + v * v2" by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1605	have "0 \<le> u * v1 + v * v2" "0 \<le> u * v1" "0 \<le> u * v1 + v * v2" "0 \<le> v * v2"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1606	apply (rule add_nonneg_nonneg)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1607	prefer 4
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1608	apply (rule add_nonneg_nonneg)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1609	apply (rule_tac [!] mult_nonneg_nonneg)
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1610	using as(1,2) obt1(1,2) obt2(1,2)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1611	apply auto
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1612	done
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1613	then show ?thesis
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1614	unfolding obt1(5) obt2(5)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1615	unfolding * and **
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1616	using False
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1617	apply (rule_tac
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1618	x = "((u * v1) / (u * v1 + v * v2)) \<^sub>R b1 + ((v v2) / (u * v1 + v * v2)) *\<^sub>R b2" in bexI)
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1619	defer
53676 476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	1620	apply (rule convexD [OF convex_convex_hull])
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1621	using obt1(4) obt2(4)
49530 7faf67b411b4 tuned; wenzelm parents: 49529 diff changeset	1622	unfolding add_divide_distrib[symmetric] and zero_le_divide_iff
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1623	apply (auto simp add: scaleR_left_distrib scaleR_right_distrib)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1624	done
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1625	qed
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1626	have u1: "u1 \<le> 1"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1627	unfolding obt1(3)[symmetric] and not_le using obt1(2) by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1628	have u2: "u2 \<le> 1"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1629	unfolding obt2(3)[symmetric] and not_le using obt2(2) by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1630	have "u1 * u + u2 * v \<le> max u1 u2 * u + max u1 u2 * v"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1631	apply (rule add_mono)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1632	apply (rule_tac [!] mult_right_mono)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1633	using as(1,2) obt1(1,2) obt2(1,2)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1634	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1635	done
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1636	also have "\<dots> \<le> 1"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1637	unfolding distrib_left[symmetric] and as(3) using u1 u2 by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1638	finally show "u \<^sub>R x + v \<^sub>R y \<in> ?hull"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1639	unfolding mem_Collect_eq
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1640	apply (rule_tac x="u * u1 + v * u2" in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1641	apply (rule conjI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1642	defer
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1643	apply (rule_tac x="1 - u * u1 - v * u2" in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1644	unfolding Bex_def
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1645	using as(1,2) obt1(1,2) obt2(1,2) **
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1646	apply (auto intro!: mult_nonneg_nonneg add_nonneg_nonneg simp add: algebra_simps)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1647	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1648	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1649	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1650
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1651
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	1652	subsubsection {* Explicit expression for convex hull *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1653
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1654	lemma convex_hull_indexed:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1655	fixes s :: "'a::real_vector set"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1656	shows "convex hull s =
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1657	{y. \<exists>k u x.
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1658	(\<forall>i\<in>{1::nat .. k}. 0 \<le> u i \<and> x i \<in> s) \<and>
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1659	(setsum u {1..k} = 1) \<and> (setsum (\<lambda>i. u i *\<^sub>R x i) {1..k} = y)}"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1660	(is "?xyz = ?hull")
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1661	apply (rule hull_unique)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1662	apply rule
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1663	defer
53676 476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	1664	apply (rule convexI)
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1665	proof -
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1666	fix x
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1667	assume "x\<in>s"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1668	then show "x \<in> ?hull"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1669	unfolding mem_Collect_eq
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1670	apply (rule_tac x=1 in exI, rule_tac x="\<lambda>x. 1" in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1671	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1672	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1673	next
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1674	fix t
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1675	assume as: "s \<subseteq> t" "convex t"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1676	show "?hull \<subseteq> t"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1677	apply rule
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1678	unfolding mem_Collect_eq
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1679	apply (elim exE conjE)
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1680	proof -
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1681	fix x k u y
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1682	assume assm:
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1683	"\<forall>i\<in>{1::nat..k}. 0 \<le> u i \<and> y i \<in> s"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1684	"setsum u {1..k} = 1" "(\<Sum>i = 1..k. u i *\<^sub>R y i) = x"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1685	show "x\<in>t"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1686	unfolding assm(3) [symmetric]
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1687	apply (rule as(2)[unfolded convex, rule_format])
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1688	using assm(1,2) as(1) apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1689	done
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1690	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1691	next
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1692	fix x y u v
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1693	assume uv: "0 \<le> u" "0 \<le> v" "u + v = (1::real)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1694	assume xy: "x \<in> ?hull" "y \<in> ?hull"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1695	from xy obtain k1 u1 x1 where
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1696	x: "\<forall>i\<in>{1::nat..k1}. 0\<le>u1 i \<and> x1 i \<in> s" "setsum u1 {Suc 0..k1} = 1" "(\<Sum>i = Suc 0..k1. u1 i *\<^sub>R x1 i) = x"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1697	by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1698	from xy obtain k2 u2 x2 where
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1699	y: "\<forall>i\<in>{1::nat..k2}. 0\<le>u2 i \<and> x2 i \<in> s" "setsum u2 {Suc 0..k2} = 1" "(\<Sum>i = Suc 0..k2. u2 i *\<^sub>R x2 i) = y"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1700	by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1701	have *: "\<And>P (x1::'a) x2 s1 s2 i.
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1702	(if P i then s1 else s2) \<^sub>R (if P i then x1 else x2) = (if P i then s1 \<^sub>R x1 else s2 *\<^sub>R x2)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1703	"{1..k1 + k2} \<inter> {1..k1} = {1..k1}" "{1..k1 + k2} \<inter> - {1..k1} = (\<lambda>i. i + k1) ` {1..k2}"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1704	prefer 3
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1705	apply (rule, rule)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1706	unfolding image_iff
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1707	apply (rule_tac x = "x - k1" in bexI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1708	apply (auto simp add: not_le)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1709	done
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1710	have inj: "inj_on (\<lambda>i. i + k1) {1..k2}"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1711	unfolding inj_on_def by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1712	show "u \<^sub>R x + v \<^sub>R y \<in> ?hull"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1713	apply rule
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1714	apply (rule_tac x="k1 + k2" in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1715	apply (rule_tac x="\<lambda>i. if i \<in> {1..k1} then u * u1 i else v * u2 (i - k1)" in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1716	apply (rule_tac x="\<lambda>i. if i \<in> {1..k1} then x1 i else x2 (i - k1)" in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1717	apply (rule, rule)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1718	defer
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1719	apply rule
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1720	unfolding * and setsum_cases[OF finite_atLeastAtMost[of 1 "k1 + k2"]] and
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1721	setsum_reindex[OF inj] and o_def Collect_mem_eq
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1722	unfolding scaleR_scaleR[symmetric] scaleR_right.setsum [symmetric] setsum_right_distrib[symmetric]
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1723	proof -
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1724	fix i
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1725	assume i: "i \<in> {1..k1+k2}"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1726	show "0 \<le> (if i \<in> {1..k1} then u * u1 i else v * u2 (i - k1)) \<and>
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1727	(if i \<in> {1..k1} then x1 i else x2 (i - k1)) \<in> s"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1728	proof (cases "i\<in>{1..k1}")
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1729	case True
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1730	then show ?thesis
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1731	using mult_nonneg_nonneg[of u "u1 i"] and uv(1) x(1)[THEN bspec[where x=i]]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1732	by auto
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1733	next
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1734	case False
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1735	def j \<equiv> "i - k1"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1736	from i False have "j \<in> {1..k2}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1737	unfolding j_def by auto
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1738	then show ?thesis
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1739	unfolding j_def[symmetric]
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1740	using False
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1741	using mult_nonneg_nonneg[of v "u2 j"] and uv(2) y(1)[THEN bspec[where x=j]]
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1742	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1743	done
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1744	qed
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1745	qed (auto simp add: not_le x(2,3) y(2,3) uv(3))
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1746	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1747
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1748	lemma convex_hull_finite:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1749	fixes s :: "'a::real_vector set"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1750	assumes "finite s"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1751	shows "convex hull s = {y. \<exists>u. (\<forall>x\<in>s. 0 \<le> u x) \<and>
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1752	setsum u s = 1 \<and> setsum (\<lambda>x. u x *\<^sub>R x) s = y}"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1753	(is "?HULL = ?set")
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1754	proof (rule hull_unique, auto simp add: convex_def[of ?set])
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1755	fix x
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1756	assume "x \<in> s"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1757	then show "\<exists>u. (\<forall>x\<in>s. 0 \<le> u x) \<and> setsum u s = 1 \<and> (\<Sum>x\<in>s. u x *\<^sub>R x) = x"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1758	apply (rule_tac x="\<lambda>y. if x=y then 1 else 0" in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1759	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1760	unfolding setsum_delta'[OF assms] and setsum_delta''[OF assms]
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1761	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1762	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1763	next
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1764	fix u v :: real
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1765	assume uv: "0 \<le> u" "0 \<le> v" "u + v = 1"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1766	fix ux assume ux: "\<forall>x\<in>s. 0 \<le> ux x" "setsum ux s = (1::real)"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1767	fix uy assume uy: "\<forall>x\<in>s. 0 \<le> uy x" "setsum uy s = (1::real)"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1768	{
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1769	fix x
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1770	assume "x\<in>s"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1771	then have "0 \<le> u * ux x + v * uy x"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1772	using ux(1)[THEN bspec[where x=x]] uy(1)[THEN bspec[where x=x]] and uv(1,2)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1773	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1774	apply (metis add_nonneg_nonneg mult_nonneg_nonneg uv(1) uv(2))
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1775	done
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1776	}
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1777	moreover
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1778	have "(\<Sum>x\<in>s. u * ux x + v * uy x) = 1"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1779	unfolding setsum_addf and setsum_right_distrib[symmetric] and ux(2) uy(2)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1780	using uv(3) by auto
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1781	moreover
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1782	have "(\<Sum>x\<in>s. (u * ux x + v * uy x) \<^sub>R x) = u \<^sub>R (\<Sum>x\<in>s. ux x \<^sub>R x) + v \<^sub>R (\<Sum>x\<in>s. uy x *\<^sub>R x)"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1783	unfolding scaleR_left_distrib and setsum_addf and scaleR_scaleR[symmetric]
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1784	and scaleR_right.setsum [symmetric]
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1785	by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1786	ultimately
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1787	show "\<exists>uc. (\<forall>x\<in>s. 0 \<le> uc x) \<and> setsum uc s = 1 \<and>
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1788	(\<Sum>x\<in>s. uc x \<^sub>R x) = u \<^sub>R (\<Sum>x\<in>s. ux x \<^sub>R x) + v \<^sub>R (\<Sum>x\<in>s. uy x *\<^sub>R x)"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1789	apply (rule_tac x="\<lambda>x. u * ux x + v * uy x" in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1790	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1791	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1792	next
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1793	fix t
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1794	assume t: "s \<subseteq> t" "convex t"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1795	fix u
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1796	assume u: "\<forall>x\<in>s. 0 \<le> u x" "setsum u s = (1::real)"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1797	then show "(\<Sum>x\<in>s. u x *\<^sub>R x) \<in> t"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1798	using t(2)[unfolded convex_explicit, THEN spec[where x=s], THEN spec[where x=u]]
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1799	using assms and t(1) by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1800	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1801
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1802
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	1803	subsubsection {* Another formulation from Lars Schewe *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1804
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1805	lemma setsum_constant_scaleR:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1806	fixes y :: "'a::real_vector"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1807	shows "(\<Sum>x\<in>A. y) = of_nat (card A) *\<^sub>R y"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1808	apply (cases "finite A")
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1809	apply (induct set: finite)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1810	apply (simp_all add: algebra_simps)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1811	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1812
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1813	lemma convex_hull_explicit:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1814	fixes p :: "'a::real_vector set"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1815	shows "convex hull p =
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1816	{y. \<exists>s u. finite s \<and> s \<subseteq> p \<and> (\<forall>x\<in>s. 0 \<le> u x) \<and> setsum u s = 1 \<and> setsum (\<lambda>v. u v *\<^sub>R v) s = y}"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1817	(is "?lhs = ?rhs")
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1818	proof -
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1819	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1820	fix x
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1821	assume "x\<in>?lhs"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1822	then obtain k u y where
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1823	obt: "\<forall>i\<in>{1::nat..k}. 0 \<le> u i \<and> y i \<in> p" "setsum u {1..k} = 1" "(\<Sum>i = 1..k. u i *\<^sub>R y i) = x"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1824	unfolding convex_hull_indexed by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1825
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1826	have fin: "finite {1..k}" by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1827	have fin': "\<And>v. finite {i \<in> {1..k}. y i = v}" by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1828	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1829	fix j
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1830	assume "j\<in>{1..k}"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1831	then have "y j \<in> p" "0 \<le> setsum u {i. Suc 0 \<le> i \<and> i \<le> k \<and> y i = y j}"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1832	using obt(1)[THEN bspec[where x=j]] and obt(2)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1833	apply simp
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1834	apply (rule setsum_nonneg)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1835	using obt(1)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1836	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1837	done
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1838	}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1839	moreover
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	1840	have "(\<Sum>v\<in>y ` {1..k}. setsum u {i \<in> {1..k}. y i = v}) = 1"
49530 7faf67b411b4 tuned; wenzelm parents: 49529 diff changeset	1841	unfolding setsum_image_gen[OF fin, symmetric] using obt(2) by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1842	moreover have "(\<Sum>v\<in>y ` {1..k}. setsum u {i \<in> {1..k}. y i = v} *\<^sub>R v) = x"
49530 7faf67b411b4 tuned; wenzelm parents: 49529 diff changeset	1843	using setsum_image_gen[OF fin, of "\<lambda>i. u i *\<^sub>R y i" y, symmetric]
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1844	unfolding scaleR_left.setsum using obt(3) by auto
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1845	ultimately
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1846	have "\<exists>s u. finite s \<and> s \<subseteq> p \<and> (\<forall>x\<in>s. 0 \<le> u x) \<and> setsum u s = 1 \<and> (\<Sum>v\<in>s. u v *\<^sub>R v) = x"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1847	apply (rule_tac x="y ` {1..k}" in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1848	apply (rule_tac x="\<lambda>v. setsum u {i\<in>{1..k}. y i = v}" in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1849	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1850	done
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1851	then have "x\<in>?rhs" by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1852	}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1853	moreover
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1854	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1855	fix y
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1856	assume "y\<in>?rhs"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1857	then obtain s u where
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1858	obt: "finite s" "s \<subseteq> p" "\<forall>x\<in>s. 0 \<le> u x" "setsum u s = 1" "(\<Sum>v\<in>s. u v *\<^sub>R v) = y"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1859	by auto
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1860
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1861	obtain f where f: "inj_on f {1..card s}" "f ` {1..card s} = s"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1862	using ex_bij_betw_nat_finite_1[OF obt(1)] unfolding bij_betw_def by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1863
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1864	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1865	fix i :: nat
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1866	assume "i\<in>{1..card s}"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1867	then have "f i \<in> s"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1868	apply (subst f(2)[symmetric])
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1869	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1870	done
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1871	then have "0 \<le> u (f i)" "f i \<in> p" using obt(2,3) by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1872	}
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	1873	moreover have *: "finite {1..card s}" by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1874	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1875	fix y
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1876	assume "y\<in>s"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1877	then obtain i where "i\<in>{1..card s}" "f i = y"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1878	using f using image_iff[of y f "{1..card s}"]
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1879	by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1880	then have "{x. Suc 0 \<le> x \<and> x \<le> card s \<and> f x = y} = {i}"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1881	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1882	using f(1)[unfolded inj_on_def]
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1883	apply(erule_tac x=x in ballE)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1884	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1885	done
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1886	then have "card {x. Suc 0 \<le> x \<and> x \<le> card s \<and> f x = y} = 1" by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1887	then have "(\<Sum>x\<in>{x \<in> {1..card s}. f x = y}. u (f x)) = u y"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1888	"(\<Sum>x\<in>{x \<in> {1..card s}. f x = y}. u (f x) \<^sub>R f x) = u y \<^sub>R y"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1889	by (auto simp add: setsum_constant_scaleR)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1890	}
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1891	then have "(\<Sum>x = 1..card s. u (f x)) = 1" "(\<Sum>i = 1..card s. u (f i) *\<^sub>R f i) = y"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1892	unfolding setsum_image_gen[OF (1), of "\<lambda>x. u (f x) \<^sub>R f x" f]
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1893	and setsum_image_gen[OF *(1), of "\<lambda>x. u (f x)" f]
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1894	unfolding f
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1895	using setsum_cong2[of s "\<lambda>y. (\<Sum>x\<in>{x \<in> {1..card s}. f x = y}. u (f x) \<^sub>R f x)" "\<lambda>v. u v \<^sub>R v"]
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1896	using setsum_cong2 [of s "\<lambda>y. (\<Sum>x\<in>{x \<in> {1..card s}. f x = y}. u (f x))" u]
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1897	unfolding obt(4,5)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1898	by auto
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1899	ultimately
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1900	have "\<exists>k u x. (\<forall>i\<in>{1..k}. 0 \<le> u i \<and> x i \<in> p) \<and> setsum u {1..k} = 1 \<and>
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1901	(\<Sum>i::nat = 1..k. u i *\<^sub>R x i) = y"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1902	apply (rule_tac x="card s" in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1903	apply (rule_tac x="u \<circ> f" in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1904	apply (rule_tac x=f in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1905	apply fastforce
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1906	done
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1907	then have "y \<in> ?lhs"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1908	unfolding convex_hull_indexed by auto
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1909	}
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1910	ultimately show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1911	unfolding set_eq_iff by blast
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1912	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1913
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1914
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	1915	subsubsection {* A stepping theorem for that expansion *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1916
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1917	lemma convex_hull_finite_step:
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1918	fixes s :: "'a::real_vector set"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1919	assumes "finite s"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1920	shows
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1921	"(\<exists>u. (\<forall>x\<in>insert a s. 0 \<le> u x) \<and> setsum u (insert a s) = w \<and> setsum (\<lambda>x. u x *\<^sub>R x) (insert a s) = y)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1922	\<longleftrightarrow> (\<exists>v\<ge>0. \<exists>u. (\<forall>x\<in>s. 0 \<le> u x) \<and> setsum u s = w - v \<and> setsum (\<lambda>x. u x \<^sub>R x) s = y - v \<^sub>R a)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1923	(is "?lhs = ?rhs")
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1924	proof (rule, case_tac[!] "a\<in>s")
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1925	assume "a \<in> s"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1926	then have *: "insert a s = s" by auto
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1927	assume ?lhs
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1928	then show ?rhs
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1929	unfolding *
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1930	apply (rule_tac x=0 in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1931	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1932	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1933	next
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1934	assume ?lhs
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1935	then obtain u where
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1936	u: "\<forall>x\<in>insert a s. 0 \<le> u x" "setsum u (insert a s) = w" "(\<Sum>x\<in>insert a s. u x *\<^sub>R x) = y"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1937	by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1938	assume "a \<notin> s"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1939	then show ?rhs
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1940	apply (rule_tac x="u a" in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1941	using u(1)[THEN bspec[where x=a]]
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1942	apply simp
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1943	apply (rule_tac x=u in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1944	using u[unfolded setsum_clauses(2)[OF assms]] and `a\<notin>s`
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1945	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1946	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1947	next
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1948	assume "a \<in> s"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1949	then have *: "insert a s = s" by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1950	have fin: "finite (insert a s)" using assms by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1951	assume ?rhs
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1952	then obtain v u where uv: "v\<ge>0" "\<forall>x\<in>s. 0 \<le> u x" "setsum u s = w - v" "(\<Sum>x\<in>s. u x \<^sub>R x) = y - v \<^sub>R a"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1953	by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1954	show ?lhs
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1955	apply (rule_tac x = "\<lambda>x. (if a = x then v else 0) + u x" in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1956	unfolding scaleR_left_distrib and setsum_addf and setsum_delta''[OF fin] and setsum_delta'[OF fin]
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1957	unfolding setsum_clauses(2)[OF assms]
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1958	using uv and uv(2)[THEN bspec[where x=a]] and `a\<in>s`
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1959	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1960	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1961	next
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1962	assume ?rhs
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1963	then obtain v u where
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	1964	uv: "v\<ge>0" "\<forall>x\<in>s. 0 \<le> u x" "setsum u s = w - v" "(\<Sum>x\<in>s. u x \<^sub>R x) = y - v \<^sub>R a"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1965	by auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1966	moreover
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1967	assume "a \<notin> s"
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1968	moreover
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1969	have "(\<Sum>x\<in>s. if a = x then v else u x) = setsum u s"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1970	and "(\<Sum>x\<in>s. (if a = x then v else u x) \<^sub>R x) = (\<Sum>x\<in>s. u x \<^sub>R x)"
50804 4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1971	apply (rule_tac setsum_cong2)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1972	defer
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1973	apply (rule_tac setsum_cong2)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1974	using `a \<notin> s`
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1975	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1976	done
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1977	ultimately show ?lhs
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1978	apply (rule_tac x="\<lambda>x. if a = x then v else u x" in exI)
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1979	unfolding setsum_clauses(2)[OF assms]
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1980	apply auto
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1981	done
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1982	qed
4156a45aeb63 tuned proofs; wenzelm parents: 50526 diff changeset	1983
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1984
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	1985	subsubsection {* Hence some special cases *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1986
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1987	lemma convex_hull_2:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	1988	"convex hull {a,b} = {u \<^sub>R a + v \<^sub>R b \| u v. 0 \<le> u \<and> 0 \<le> v \<and> u + v = 1}"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1989	proof -
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1990	have *: "\<And>u. (\<forall>x\<in>{a, b}. 0 \<le> u x) \<longleftrightarrow> 0 \<le> u a \<and> 0 \<le> u b"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1991	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1992	have **: "finite {b}" by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1993	show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1994	apply (simp add: convex_hull_finite)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1995	unfolding convex_hull_finite_step[OF *, of a 1, unfolded conj_assoc]
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1996	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1997	apply (rule_tac x=v in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1998	apply (rule_tac x="1 - v" in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	1999	apply simp
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2000	apply (rule_tac x=u in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2001	apply simp
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2002	apply (rule_tac x="\<lambda>x. v" in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2003	apply simp
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2004	done
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2005	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2006
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2007	lemma convex_hull_2_alt: "convex hull {a,b} = {a + u *\<^sub>R (b - a) \| u. 0 \<le> u \<and> u \<le> 1}"
44170 510ac30f44c0 make Multivariate_Analysis work with separate set type huffman parents: 44142 diff changeset	2008	unfolding convex_hull_2
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2009	proof (rule Collect_cong)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2010	have *: "\<And>x y ::real. x + y = 1 \<longleftrightarrow> x = 1 - y"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2011	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2012	fix x
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2013	show "(\<exists>v u. x = v \<^sub>R a + u \<^sub>R b \<and> 0 \<le> v \<and> 0 \<le> u \<and> v + u = 1) \<longleftrightarrow>
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2014	(\<exists>u. x = a + u *\<^sub>R (b - a) \<and> 0 \<le> u \<and> u \<le> 1)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2015	unfolding *
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2016	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2017	apply (rule_tac[!] x=u in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2018	apply (auto simp add: algebra_simps)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2019	done
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2020	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2021
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2022	lemma convex_hull_3:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2023	"convex hull {a,b,c} = { u \<^sub>R a + v \<^sub>R b + w *\<^sub>R c \| u v w. 0 \<le> u \<and> 0 \<le> v \<and> 0 \<le> w \<and> u + v + w = 1}"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2024	proof -
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2025	have fin: "finite {a,b,c}" "finite {b,c}" "finite {c}"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2026	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2027	have *: "\<And>x y z ::real. x + y + z = 1 \<longleftrightarrow> x = 1 - y - z"
44361 75ec83d45303 remove unnecessary euclidean_space class constraints huffman parents: 44349 diff changeset	2028	by (auto simp add: field_simps)
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2029	show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2030	unfolding convex_hull_finite[OF fin(1)] and convex_hull_finite_step[OF fin(2)] and *
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2031	unfolding convex_hull_finite_step[OF fin(3)]
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2032	apply (rule Collect_cong)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2033	apply simp
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2034	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2035	apply (rule_tac x=va in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2036	apply (rule_tac x="u c" in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2037	apply simp
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2038	apply (rule_tac x="1 - v - w" in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2039	apply simp
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2040	apply (rule_tac x=v in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2041	apply simp
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2042	apply (rule_tac x="\<lambda>x. w" in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2043	apply simp
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2044	done
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2045	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2046
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2047	lemma convex_hull_3_alt:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2048	"convex hull {a,b,c} = {a + u \<^sub>R (b - a) + v \<^sub>R (c - a) \| u v. 0 \<le> u \<and> 0 \<le> v \<and> u + v \<le> 1}"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2049	proof -
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2050	have *: "\<And>x y z ::real. x + y + z = 1 \<longleftrightarrow> x = 1 - y - z"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2051	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2052	show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2053	unfolding convex_hull_3
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2054	apply (auto simp add: *)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2055	apply (rule_tac x=v in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2056	apply (rule_tac x=w in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2057	apply (simp add: algebra_simps)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2058	apply (rule_tac x=u in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2059	apply (rule_tac x=v in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2060	apply (simp add: algebra_simps)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2061	done
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2062	qed
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2063
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2064
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	2065	subsection {* Relations among closure notions and corresponding hulls *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2066
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2067	lemma affine_imp_convex: "affine s \<Longrightarrow> convex s"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2068	unfolding affine_def convex_def by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2069
44361 75ec83d45303 remove unnecessary euclidean_space class constraints huffman parents: 44349 diff changeset	2070	lemma subspace_imp_convex: "subspace s \<Longrightarrow> convex s"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2071	using subspace_imp_affine affine_imp_convex by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2072
44361 75ec83d45303 remove unnecessary euclidean_space class constraints huffman parents: 44349 diff changeset	2073	lemma affine_hull_subset_span: "(affine hull s) \<subseteq> (span s)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2074	by (metis hull_minimal span_inc subspace_imp_affine subspace_span)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2075
44361 75ec83d45303 remove unnecessary euclidean_space class constraints huffman parents: 44349 diff changeset	2076	lemma convex_hull_subset_span: "(convex hull s) \<subseteq> (span s)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2077	by (metis hull_minimal span_inc subspace_imp_convex subspace_span)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2078
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2079	lemma convex_hull_subset_affine_hull: "(convex hull s) \<subseteq> (affine hull s)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2080	by (metis affine_affine_hull affine_imp_convex hull_minimal hull_subset)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2081
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2082
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2083	lemma affine_dependent_imp_dependent: "affine_dependent s \<Longrightarrow> dependent s"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	2084	unfolding affine_dependent_def dependent_def
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2085	using affine_hull_subset_span by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2086
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2087	lemma dependent_imp_affine_dependent:
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2088	assumes "dependent {x - a\| x . x \<in> s}"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2089	and "a \<notin> s"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2090	shows "affine_dependent (insert a s)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2091	proof -
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	2092	from assms(1)[unfolded dependent_explicit] obtain S u v
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2093	where obt: "finite S" "S \<subseteq> {x - a \|x. x \<in> s}" "v\<in>S" "u v \<noteq> 0" "(\<Sum>v\<in>S. u v *\<^sub>R v) = 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2094	by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2095	def t \<equiv> "(\<lambda>x. x + a) ` S"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2096
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2097	have inj: "inj_on (\<lambda>x. x + a) S"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2098	unfolding inj_on_def by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2099	have "0 \<notin> S"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2100	using obt(2) assms(2) unfolding subset_eq by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2101	have fin: "finite t" and "t \<subseteq> s"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2102	unfolding t_def using obt(1,2) by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2103	then have "finite (insert a t)" and "insert a t \<subseteq> insert a s"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2104	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2105	moreover have *: "\<And>P Q. (\<Sum>x\<in>t. (if x = a then P x else Q x)) = (\<Sum>x\<in>t. Q x)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2106	apply (rule setsum_cong2)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2107	using `a\<notin>s` `t\<subseteq>s`
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2108	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2109	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2110	have "(\<Sum>x\<in>insert a t. if x = a then - (\<Sum>x\<in>t. u (x - a)) else u (x - a)) = 0"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2111	unfolding setsum_clauses(2)[OF fin]
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2112	using `a\<notin>s` `t\<subseteq>s`
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2113	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2114	unfolding *
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2115	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2116	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2117	moreover have "\<exists>v\<in>insert a t. (if v = a then - (\<Sum>x\<in>t. u (x - a)) else u (v - a)) \<noteq> 0"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2118	apply (rule_tac x="v + a" in bexI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2119	using obt(3,4) and `0\<notin>S`
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2120	unfolding t_def
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2121	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2122	done
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2123	moreover have : "\<And>P Q. (\<Sum>x\<in>t. (if x = a then P x else Q x) \<^sub>R x) = (\<Sum>x\<in>t. Q x *\<^sub>R x)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2124	apply (rule setsum_cong2)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2125	using `a\<notin>s` `t\<subseteq>s`
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2126	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2127	done
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	2128	have "(\<Sum>x\<in>t. u (x - a)) \<^sub>R a = (\<Sum>v\<in>t. u (v - a) \<^sub>R v)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2129	unfolding scaleR_left.setsum
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2130	unfolding t_def and setsum_reindex[OF inj] and o_def
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2131	using obt(5)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2132	by (auto simp add: setsum_addf scaleR_right_distrib)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2133	then have "(\<Sum>v\<in>insert a t. (if v = a then - (\<Sum>x\<in>t. u (x - a)) else u (v - a)) *\<^sub>R v) = 0"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2134	unfolding setsum_clauses(2)[OF fin]
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2135	using `a\<notin>s` `t\<subseteq>s`
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2136	by (auto simp add: *)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2137	ultimately show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2138	unfolding affine_dependent_explicit
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2139	apply (rule_tac x="insert a t" in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2140	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2141	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2142	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2143
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2144	lemma convex_cone:
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2145	"convex s \<and> cone s \<longleftrightarrow> (\<forall>x\<in>s. \<forall>y\<in>s. (x + y) \<in> s) \<and> (\<forall>x\<in>s. \<forall>c\<ge>0. (c *\<^sub>R x) \<in> s)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2146	(is "?lhs = ?rhs")
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2147	proof -
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2148	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2149	fix x y
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2150	assume "x\<in>s" "y\<in>s" and ?lhs
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2151	then have "2 \<^sub>R x \<in>s" "2 \<^sub>R y \<in> s"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2152	unfolding cone_def by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2153	then have "x + y \<in> s"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2154	using `?lhs`[unfolded convex_def, THEN conjunct1]
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2155	apply (erule_tac x="2*\<^sub>R x" in ballE)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2156	apply (erule_tac x="2*\<^sub>R y" in ballE)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2157	apply (erule_tac x="1/2" in allE)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2158	apply simp
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2159	apply (erule_tac x="1/2" in allE)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2160	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2161	done
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2162	}
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2163	then show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2164	unfolding convex_def cone_def by blast
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2165	qed
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2166
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2167	lemma affine_dependent_biggerset:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2168	fixes s :: "'a::euclidean_space set"
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	2169	assumes "finite s" "card s \<ge> DIM('a) + 2"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2170	shows "affine_dependent s"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2171	proof -
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2172	have "s \<noteq> {}" using assms by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2173	then obtain a where "a\<in>s" by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2174	have *: "{x - a \|x. x \<in> s - {a}} = (\<lambda>x. x - a) ` (s - {a})"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2175	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2176	have "card {x - a \|x. x \<in> s - {a}} = card (s - {a})"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2177	unfolding *
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2178	apply (rule card_image)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2179	unfolding inj_on_def
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2180	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2181	done
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	2182	also have "\<dots> > DIM('a)" using assms(2)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2183	unfolding card_Diff_singleton[OF assms(1) `a\<in>s`] by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2184	finally show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2185	apply (subst insert_Diff[OF `a\<in>s`, symmetric])
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2186	apply (rule dependent_imp_affine_dependent)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2187	apply (rule dependent_biggerset)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2188	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2189	done
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2190	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2191
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2192	lemma affine_dependent_biggerset_general:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2193	assumes "finite (s :: 'a::euclidean_space set)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2194	and "card s \<ge> dim s + 2"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2195	shows "affine_dependent s"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2196	proof -
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2197	from assms(2) have "s \<noteq> {}" by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2198	then obtain a where "a\<in>s" by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2199	have *: "{x - a \|x. x \<in> s - {a}} = (\<lambda>x. x - a) ` (s - {a})"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2200	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2201	have **: "card {x - a \|x. x \<in> s - {a}} = card (s - {a})"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2202	unfolding *
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2203	apply (rule card_image)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2204	unfolding inj_on_def
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2205	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2206	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2207	have "dim {x - a \|x. x \<in> s - {a}} \<le> dim s"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2208	apply (rule subset_le_dim)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2209	unfolding subset_eq
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2210	using `a\<in>s`
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2211	apply (auto simp add:span_superset span_sub)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2212	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2213	also have "\<dots> < dim s + 1" by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2214	also have "\<dots> \<le> card (s - {a})"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2215	using assms
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2216	using card_Diff_singleton[OF assms(1) `a\<in>s`]
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2217	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2218	finally show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2219	apply (subst insert_Diff[OF `a\<in>s`, symmetric])
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2220	apply (rule dependent_imp_affine_dependent)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2221	apply (rule dependent_biggerset_general)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2222	unfolding **
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2223	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2224	done
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2225	qed
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2226
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2227
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2228	subsection {* Caratheodory's theorem. *}
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2229
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2230	lemma convex_hull_caratheodory:
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2231	fixes p :: "('a::euclidean_space) set"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2232	shows "convex hull p =
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2233	{y. \<exists>s u. finite s \<and> s \<subseteq> p \<and> card s \<le> DIM('a) + 1 \<and>
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2234	(\<forall>x\<in>s. 0 \<le> u x) \<and> setsum u s = 1 \<and> setsum (\<lambda>v. u v *\<^sub>R v) s = y}"
39302 d7728f65b353 renamed lemmas: ext_iff -> fun_eq_iff, set_ext_iff -> set_eq_iff, set_ext -> set_eqI nipkow parents: 39198 diff changeset	2235	unfolding convex_hull_explicit set_eq_iff mem_Collect_eq
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2236	proof (rule, rule)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2237	fix y
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2238	let ?P = "\<lambda>n. \<exists>s u. finite s \<and> card s = n \<and> s \<subseteq> p \<and> (\<forall>x\<in>s. 0 \<le> u x) \<and>
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2239	setsum u s = 1 \<and> (\<Sum>v\<in>s. u v *\<^sub>R v) = y"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2240	assume "\<exists>s u. finite s \<and> s \<subseteq> p \<and> (\<forall>x\<in>s. 0 \<le> u x) \<and> setsum u s = 1 \<and> (\<Sum>v\<in>s. u v *\<^sub>R v) = y"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2241	then obtain N where "?P N" by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2242	then have "\<exists>n\<le>N. (\<forall>k<n. \<not> ?P k) \<and> ?P n"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2243	apply (rule_tac ex_least_nat_le)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2244	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2245	done
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2246	then obtain n where "?P n" and smallest: "\<forall>k<n. \<not> ?P k"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2247	by blast
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2248	then obtain s u where obt: "finite s" "card s = n" "s\<subseteq>p" "\<forall>x\<in>s. 0 \<le> u x"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2249	"setsum u s = 1" "(\<Sum>v\<in>s. u v *\<^sub>R v) = y" by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2250
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2251	have "card s \<le> DIM('a) + 1"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2252	proof (rule ccontr, simp only: not_le)
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	2253	assume "DIM('a) + 1 < card s"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2254	then have "affine_dependent s"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2255	using affine_dependent_biggerset[OF obt(1)] by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2256	then obtain w v where wv: "setsum w s = 0" "v\<in>s" "w v \<noteq> 0" "(\<Sum>v\<in>s. w v *\<^sub>R v) = 0"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2257	using affine_dependent_explicit_finite[OF obt(1)] by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2258	def i \<equiv> "(\<lambda>v. (u v) / (- w v)) ` {v\<in>s. w v < 0}"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2259	def t \<equiv> "Min i"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2260	have "\<exists>x\<in>s. w x < 0"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2261	proof (rule ccontr, simp add: not_less)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2262	assume as:"\<forall>x\<in>s. 0 \<le> w x"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2263	then have "setsum w (s - {v}) \<ge> 0"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2264	apply (rule_tac setsum_nonneg)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2265	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2266	done
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2267	then have "setsum w s > 0"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2268	unfolding setsum_diff1'[OF obt(1) `v\<in>s`]
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2269	using as[THEN bspec[where x=v]] and `v\<in>s`
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2270	using `w v \<noteq> 0`
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2271	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2272	then show False using wv(1) by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2273	qed
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2274	then have "i \<noteq> {}" unfolding i_def by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2275
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2276	then have "t \<ge> 0"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2277	using Min_ge_iff[of i 0 ] and obt(1)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2278	unfolding t_def i_def
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2279	using obt(4)[unfolded le_less]
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2280	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2281	unfolding divide_le_0_iff
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2282	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2283	done
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2284	have t: "\<forall>v\<in>s. u v + t * w v \<ge> 0"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2285	proof
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2286	fix v
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2287	assume "v \<in> s"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2288	then have v: "0 \<le> u v"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2289	using obt(4)[THEN bspec[where x=v]] by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2290	show "0 \<le> u v + t * w v"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2291	proof (cases "w v < 0")
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2292	case False
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2293	then show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2294	apply (rule_tac add_nonneg_nonneg)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2295	using v
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2296	apply simp
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2297	apply (rule mult_nonneg_nonneg)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2298	using `t\<ge>0`
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2299	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2300	done
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2301	next
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2302	case True
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2303	then have "t \<le> u v / (- w v)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2304	using `v\<in>s`
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2305	unfolding t_def i_def
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2306	apply (rule_tac Min_le)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2307	using obt(1)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2308	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2309	done
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2310	then show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2311	unfolding real_0_le_add_iff
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2312	using pos_le_divide_eq[OF True[unfolded neg_0_less_iff_less[symmetric]]]
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2313	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2314	qed
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2315	qed
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2316
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2317	obtain a where "a \<in> s" and "t = (\<lambda>v. (u v) / (- w v)) a" and "w a < 0"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2318	using Min_in[OF _ `i\<noteq>{}`] and obt(1) unfolding i_def t_def by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2319	then have a: "a \<in> s" "u a + t * w a = 0" by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2320	have *: "\<And>f. setsum f (s - {a}) = setsum f s - ((f a)::'b::ab_group_add)"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	2321	unfolding setsum_diff1'[OF obt(1) `a\<in>s`] by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2322	have "(\<Sum>v\<in>s. u v + t * w v) = 1"
49530 7faf67b411b4 tuned; wenzelm parents: 49529 diff changeset	2323	unfolding setsum_addf wv(1) setsum_right_distrib[symmetric] obt(5) by auto
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	2324	moreover have "(\<Sum>v\<in>s. u v \<^sub>R v + (t w v) \<^sub>R v) - (u a \<^sub>R a + (t * w a) *\<^sub>R a) = y"
49530 7faf67b411b4 tuned; wenzelm parents: 49529 diff changeset	2325	unfolding setsum_addf obt(6) scaleR_scaleR[symmetric] scaleR_right.setsum [symmetric] wv(4)
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	2326	using a(2) [THEN eq_neg_iff_add_eq_0 [THEN iffD2]] by simp
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2327	ultimately have "?P (n - 1)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2328	apply (rule_tac x="(s - {a})" in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2329	apply (rule_tac x="\<lambda>v. u v + t * w v" in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2330	using obt(1-3) and t and a
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2331	apply (auto simp add: * scaleR_left_distrib)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2332	done
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2333	then show False
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2334	using smallest[THEN spec[where x="n - 1"]] by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2335	qed
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2336	then show "\<exists>s u. finite s \<and> s \<subseteq> p \<and> card s \<le> DIM('a) + 1 \<and>
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2337	(\<forall>x\<in>s. 0 \<le> u x) \<and> setsum u s = 1 \<and> (\<Sum>v\<in>s. u v *\<^sub>R v) = y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2338	using obt by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2339	qed auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2340
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2341	lemma caratheodory:
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2342	"convex hull p =
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2343	{x::'a::euclidean_space. \<exists>s. finite s \<and> s \<subseteq> p \<and>
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	2344	card s \<le> DIM('a) + 1 \<and> x \<in> convex hull s}"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2345	unfolding set_eq_iff
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2346	apply rule
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2347	apply rule
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2348	unfolding mem_Collect_eq
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2349	proof -
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2350	fix x
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2351	assume "x \<in> convex hull p"
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	2352	then obtain s u where "finite s" "s \<subseteq> p" "card s \<le> DIM('a) + 1"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2353	"\<forall>x\<in>s. 0 \<le> u x" "setsum u s = 1" "(\<Sum>v\<in>s. u v *\<^sub>R v) = x"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2354	unfolding convex_hull_caratheodory by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2355	then show "\<exists>s. finite s \<and> s \<subseteq> p \<and> card s \<le> DIM('a) + 1 \<and> x \<in> convex hull s"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2356	apply (rule_tac x=s in exI)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2357	using hull_subset[of s convex]
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2358	using convex_convex_hull[unfolded convex_explicit, of s,
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2359	THEN spec[where x=s], THEN spec[where x=u]]
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2360	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2361	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2362	next
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2363	fix x
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2364	assume "\<exists>s. finite s \<and> s \<subseteq> p \<and> card s \<le> DIM('a) + 1 \<and> x \<in> convex hull s"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2365	then obtain s where "finite s" "s \<subseteq> p" "card s \<le> DIM('a) + 1" "x \<in> convex hull s"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2366	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2367	then show "x \<in> convex hull p"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2368	using hull_mono[OF `s\<subseteq>p`] by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2369	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	2370
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2371
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2372	subsection {* Some Properties of Affine Dependent Sets *}
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2373
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2374	lemma affine_independent_empty: "\<not> affine_dependent {}"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2375	by (simp add: affine_dependent_def)
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2376
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2377	lemma affine_independent_sing: "\<not> affine_dependent {a}"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2378	by (simp add: affine_dependent_def)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2379
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2380	lemma affine_hull_translation: "affine hull ((\<lambda>x. a + x) ` S) = (\<lambda>x. a + x) ` (affine hull S)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2381	proof -
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2382	have "affine ((\<lambda>x. a + x) ` (affine hull S))"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2383	using affine_translation affine_affine_hull by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2384	moreover have "(\<lambda>x. a + x) ` S \<subseteq> (\<lambda>x. a + x) ` (affine hull S)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2385	using hull_subset[of S] by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2386	ultimately have h1: "affine hull ((\<lambda>x. a + x) ` S) \<subseteq> (\<lambda>x. a + x) ` (affine hull S)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2387	by (metis hull_minimal)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2388	have "affine((\<lambda>x. -a + x) ` (affine hull ((\<lambda>x. a + x) ` S)))"
54230 b1d955791529 more simplification rules on unary and binary minus haftmann parents: 53676 diff changeset	2389	using affine_translation affine_affine_hull by (auto simp del: uminus_add_conv_diff)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2390	moreover have "(\<lambda>x. -a + x) ` (\<lambda>x. a + x) ` S \<subseteq> (\<lambda>x. -a + x) ` (affine hull ((\<lambda>x. a + x) ` S))"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2391	using hull_subset[of "(\<lambda>x. a + x) ` S"] by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2392	moreover have "S = (\<lambda>x. -a + x) ` (\<lambda>x. a + x) ` S"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2393	using translation_assoc[of "-a" a] by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2394	ultimately have "(\<lambda>x. -a + x) ` (affine hull ((\<lambda>x. a + x) ` S)) >= (affine hull S)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2395	by (metis hull_minimal)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2396	then have "affine hull ((\<lambda>x. a + x) ` S) >= (\<lambda>x. a + x) ` (affine hull S)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2397	by auto
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2398	then show ?thesis using h1 by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2399	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2400
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2401	lemma affine_dependent_translation:
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2402	assumes "affine_dependent S"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2403	shows "affine_dependent ((\<lambda>x. a + x) ` S)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2404	proof -
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2405	obtain x where x: "x \<in> S \<and> x \<in> affine hull (S - {x})"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2406	using assms affine_dependent_def by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2407	have "op + a ` (S - {x}) = op + a ` S - {a + x}"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2408	by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2409	then have "a + x \<in> affine hull ((\<lambda>x. a + x) ` S - {a + x})"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2410	using affine_hull_translation[of a "S - {x}"] x by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2411	moreover have "a + x \<in> (\<lambda>x. a + x) ` S"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2412	using x by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2413	ultimately show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2414	unfolding affine_dependent_def by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2415	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2416
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2417	lemma affine_dependent_translation_eq:
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2418	"affine_dependent S \<longleftrightarrow> affine_dependent ((\<lambda>x. a + x) ` S)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2419	proof -
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2420	{
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2421	assume "affine_dependent ((\<lambda>x. a + x) ` S)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2422	then have "affine_dependent S"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2423	using affine_dependent_translation[of "((\<lambda>x. a + x) ` S)" "-a"] translation_assoc[of "-a" a]
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2424	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2425	}
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2426	then show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2427	using affine_dependent_translation by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2428	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2429
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2430	lemma affine_hull_0_dependent:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2431	assumes "0 \<in> affine hull S"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2432	shows "dependent S"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2433	proof -
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2434	obtain s u where s_u: "finite s \<and> s \<noteq> {} \<and> s \<subseteq> S \<and> setsum u s = 1 \<and> (\<Sum>v\<in>s. u v *\<^sub>R v) = 0"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2435	using assms affine_hull_explicit[of S] by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2436	then have "\<exists>v\<in>s. u v \<noteq> 0"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2437	using setsum_not_0[of "u" "s"] by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2438	then have "finite s \<and> s \<subseteq> S \<and> (\<exists>v\<in>s. u v \<noteq> 0 \<and> (\<Sum>v\<in>s. u v *\<^sub>R v) = 0)"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2439	using s_u by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2440	then show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2441	unfolding dependent_explicit[of S] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2442	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2443
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2444	lemma affine_dependent_imp_dependent2:
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2445	assumes "affine_dependent (insert 0 S)"
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2446	shows "dependent S"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2447	proof -
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2448	obtain x where x: "x \<in> insert 0 S \<and> x \<in> affine hull (insert 0 S - {x})"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2449	using affine_dependent_def[of "(insert 0 S)"] assms by blast
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2450	then have "x \<in> span (insert 0 S - {x})"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2451	using affine_hull_subset_span by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2452	moreover have "span (insert 0 S - {x}) = span (S - {x})"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2453	using insert_Diff_if[of "0" S "{x}"] span_insert_0[of "S-{x}"] by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2454	ultimately have "x \<in> span (S - {x})" by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2455	then have "x \<noteq> 0 \<Longrightarrow> dependent S"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2456	using x dependent_def by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2457	moreover
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2458	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2459	assume "x = 0"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2460	then have "0 \<in> affine hull S"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2461	using x hull_mono[of "S - {0}" S] by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2462	then have "dependent S"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2463	using affine_hull_0_dependent by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2464	}
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2465	ultimately show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2466	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2467
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2468	lemma affine_dependent_iff_dependent:
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2469	assumes "a \<notin> S"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2470	shows "affine_dependent (insert a S) \<longleftrightarrow> dependent ((\<lambda>x. -a + x) ` S)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2471	proof -
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2472	have "(op + (- a) ` S) = {x - a\| x . x : S}" by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2473	then show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2474	using affine_dependent_translation_eq[of "(insert a S)" "-a"]
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	2475	affine_dependent_imp_dependent2 assms
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2476	dependent_imp_affine_dependent[of a S]
54230 b1d955791529 more simplification rules on unary and binary minus haftmann parents: 53676 diff changeset	2477	by (auto simp del: uminus_add_conv_diff)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2478	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2479
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2480	lemma affine_dependent_iff_dependent2:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2481	assumes "a \<in> S"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2482	shows "affine_dependent S \<longleftrightarrow> dependent ((\<lambda>x. -a + x) ` (S-{a}))"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2483	proof -
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2484	have "insert a (S - {a}) = S"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2485	using assms by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2486	then show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2487	using assms affine_dependent_iff_dependent[of a "S-{a}"] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2488	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2489
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2490	lemma affine_hull_insert_span_gen:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2491	"affine hull (insert a s) = (\<lambda>x. a + x) ` span ((\<lambda>x. - a + x) ` s)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2492	proof -
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2493	have h1: "{x - a \|x. x \<in> s} = ((\<lambda>x. -a+x) ` s)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2494	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2495	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2496	assume "a \<notin> s"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2497	then have ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2498	using affine_hull_insert_span[of a s] h1 by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2499	}
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2500	moreover
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2501	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2502	assume a1: "a \<in> s"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2503	have "\<exists>x. x \<in> s \<and> -a+x=0"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2504	apply (rule exI[of _ a])
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2505	using a1
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2506	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2507	done
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2508	then have "insert 0 ((\<lambda>x. -a+x) ` (s - {a})) = (\<lambda>x. -a+x) ` s"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2509	by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2510	then have "span ((\<lambda>x. -a+x) ` (s - {a}))=span ((\<lambda>x. -a+x) ` s)"
54230 b1d955791529 more simplification rules on unary and binary minus haftmann parents: 53676 diff changeset	2511	using span_insert_0[of "op + (- a) ` (s - {a})"] by (auto simp del: uminus_add_conv_diff)
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2512	moreover have "{x - a \|x. x \<in> (s - {a})} = ((\<lambda>x. -a+x) ` (s - {a}))"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2513	by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2514	moreover have "insert a (s - {a}) = insert a s"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2515	using assms by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2516	ultimately have ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2517	using assms affine_hull_insert_span[of "a" "s-{a}"] by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2518	}
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2519	ultimately show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2520	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2521
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2522	lemma affine_hull_span2:
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2523	assumes "a \<in> s"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2524	shows "affine hull s = (\<lambda>x. a+x) ` span ((\<lambda>x. -a+x) ` (s-{a}))"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2525	using affine_hull_insert_span_gen[of a "s - {a}", unfolded insert_Diff[OF assms]]
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2526	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2527
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2528	lemma affine_hull_span_gen:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2529	assumes "a \<in> affine hull s"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2530	shows "affine hull s = (\<lambda>x. a+x) ` span ((\<lambda>x. -a+x) ` s)"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2531	proof -
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2532	have "affine hull (insert a s) = affine hull s"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2533	using hull_redundant[of a affine s] assms by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2534	then show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2535	using affine_hull_insert_span_gen[of a "s"] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2536	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2537
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2538	lemma affine_hull_span_0:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2539	assumes "0 \<in> affine hull S"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2540	shows "affine hull S = span S"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2541	using affine_hull_span_gen[of "0" S] assms by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2542
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2543
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2544	lemma extend_to_affine_basis:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2545	fixes S V :: "'n::euclidean_space set"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2546	assumes "\<not> affine_dependent S" "S \<subseteq> V" "S \<noteq> {}"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2547	shows "\<exists>T. \<not> affine_dependent T \<and> S \<subseteq> T \<and> T \<subseteq> V \<and> affine hull T = affine hull V"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2548	proof -
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2549	obtain a where a: "a \<in> S"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2550	using assms by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2551	then have h0: "independent ((\<lambda>x. -a + x) ` (S-{a}))"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2552	using affine_dependent_iff_dependent2 assms by auto
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2553	then obtain B where B:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2554	"(\<lambda>x. -a+x) ` (S - {a}) \<subseteq> B \<and> B \<subseteq> (\<lambda>x. -a+x) ` V \<and> independent B \<and> (\<lambda>x. -a+x) ` V \<subseteq> span B"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2555	using maximal_independent_subset_extend[of "(\<lambda>x. -a+x) ` (S-{a})" "(\<lambda>x. -a + x) ` V"] assms
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2556	by blast
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2557	def T \<equiv> "(\<lambda>x. a+x) ` insert 0 B"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2558	then have "T = insert a ((\<lambda>x. a+x) ` B)"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2559	by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2560	then have "affine hull T = (\<lambda>x. a+x) ` span B"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2561	using affine_hull_insert_span_gen[of a "((\<lambda>x. a+x) ` B)"] translation_assoc[of "-a" a B]
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2562	by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2563	then have "V \<subseteq> affine hull T"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2564	using B assms translation_inverse_subset[of a V "span B"]
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2565	by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2566	moreover have "T \<subseteq> V"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2567	using T_def B a assms by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2568	ultimately have "affine hull T = affine hull V"
44457 d366fa5551ef declare euclidean_simps [simp] at the point they are proved; huffman parents: 44365 diff changeset	2569	by (metis Int_absorb1 Int_absorb2 hull_hull hull_mono)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2570	moreover have "S \<subseteq> T"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2571	using T_def B translation_inverse_subset[of a "S-{a}" B]
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2572	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2573	moreover have "\<not> affine_dependent T"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2574	using T_def affine_dependent_translation_eq[of "insert 0 B"]
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2575	affine_dependent_imp_dependent2 B
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2576	by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2577	ultimately show ?thesis using `T \<subseteq> V` by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2578	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2579
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	2580	lemma affine_basis_exists:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2581	fixes V :: "'n::euclidean_space set"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2582	shows "\<exists>B. B \<subseteq> V \<and> \<not> affine_dependent B \<and> affine hull V = affine hull B"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2583	proof (cases "V = {}")
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2584	case True
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2585	then show ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2586	using affine_independent_empty by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2587	next
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2588	case False
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2589	then obtain x where "x \<in> V" by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2590	then show ?thesis
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2591	using affine_dependent_def[of "{x}"] extend_to_affine_basis[of "{x}" V]
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2592	by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2593	qed
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2594
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2595
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2596	subsection {* Affine Dimension of a Set *}
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2597
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2598	definition "aff_dim V =
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2599	(SOME d :: int.
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2600	\<exists>B. affine hull B = affine hull V \<and> \<not> affine_dependent B \<and> of_nat (card B) = d + 1)"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2601
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2602	lemma aff_dim_basis_exists:
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	2603	fixes V :: "('n::euclidean_space) set"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2604	shows "\<exists>B. affine hull B = affine hull V \<and> \<not> affine_dependent B \<and> of_nat (card B) = aff_dim V + 1"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2605	proof -
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2606	obtain B where "\<not> affine_dependent B \<and> affine hull B = affine hull V"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2607	using affine_basis_exists[of V] by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2608	then show ?thesis
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2609	unfolding aff_dim_def
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2610	some_eq_ex[of "\<lambda>d. \<exists>B. affine hull B = affine hull V \<and> \<not> affine_dependent B \<and> of_nat (card B) = d + 1"]
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2611	apply auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2612	apply (rule exI[of _ "int (card B) - (1 :: int)"])
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2613	apply (rule exI[of _ "B"])
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2614	apply auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2615	done
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2616	qed
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2617
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2618	lemma affine_hull_nonempty: "S \<noteq> {} \<longleftrightarrow> affine hull S \<noteq> {}"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2619	proof -
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2620	have "S = {} \<Longrightarrow> affine hull S = {}"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2621	using affine_hull_empty by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2622	moreover have "affine hull S = {} \<Longrightarrow> S = {}"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2623	unfolding hull_def by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2624	ultimately show ?thesis by blast
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2625	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2626
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2627	lemma aff_dim_parallel_subspace_aux:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2628	fixes B :: "'n::euclidean_space set"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2629	assumes "\<not> affine_dependent B" "a \<in> B"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2630	shows "finite B \<and> ((card B) - 1 = dim (span ((\<lambda>x. -a+x) ` (B-{a}))))"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2631	proof -
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2632	have "independent ((\<lambda>x. -a + x) ` (B-{a}))"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2633	using affine_dependent_iff_dependent2 assms by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2634	then have fin: "dim (span ((\<lambda>x. -a+x) ` (B-{a}))) = card ((\<lambda>x. -a + x) ` (B-{a}))"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2635	"finite ((\<lambda>x. -a + x) ` (B - {a}))"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2636	using indep_card_eq_dim_span[of "(\<lambda>x. -a+x) ` (B-{a})"] by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2637	show ?thesis
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2638	proof (cases "(\<lambda>x. -a + x) ` (B - {a}) = {}")
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2639	case True
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2640	have "B = insert a ((\<lambda>x. a + x) ` (\<lambda>x. -a + x) ` (B - {a}))"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2641	using translation_assoc[of "a" "-a" "(B - {a})"] assms by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2642	then have "B = {a}" using True by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2643	then show ?thesis using assms fin by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2644	next
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2645	case False
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2646	then have "card ((\<lambda>x. -a + x) ` (B - {a})) > 0"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2647	using fin by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2648	moreover have h1: "card ((\<lambda>x. -a + x) ` (B-{a})) = card (B-{a})"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2649	apply (rule card_image)
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2650	using translate_inj_on
54230 b1d955791529 more simplification rules on unary and binary minus haftmann parents: 53676 diff changeset	2651	apply (auto simp del: uminus_add_conv_diff)
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2652	done
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2653	ultimately have "card (B-{a}) > 0" by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2654	then have *: "finite (B - {a})"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2655	using card_gt_0_iff[of "(B - {a})"] by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2656	then have "card (B - {a}) = card B - 1"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2657	using card_Diff_singleton assms by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2658	with * show ?thesis using fin h1 by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2659	qed
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2660	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2661
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2662	lemma aff_dim_parallel_subspace:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2663	fixes V L :: "'n::euclidean_space set"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2664	assumes "V \<noteq> {}"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2665	and "subspace L"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2666	and "affine_parallel (affine hull V) L"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2667	shows "aff_dim V = int (dim L)"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2668	proof -
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2669	obtain B where
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2670	B: "affine hull B = affine hull V \<and> \<not> affine_dependent B \<and> int (card B) = aff_dim V + 1"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2671	using aff_dim_basis_exists by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2672	then have "B \<noteq> {}"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2673	using assms B affine_hull_nonempty[of V] affine_hull_nonempty[of B]
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2674	by auto
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2675	then obtain a where a: "a \<in> B" by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2676	def Lb \<equiv> "span ((\<lambda>x. -a+x) ` (B-{a}))"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2677	moreover have "affine_parallel (affine hull B) Lb"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2678	using Lb_def B assms affine_hull_span2[of a B] a
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2679	affine_parallel_commut[of "Lb" "(affine hull B)"]
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2680	unfolding affine_parallel_def
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2681	by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2682	moreover have "subspace Lb"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2683	using Lb_def subspace_span by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2684	moreover have "affine hull B \<noteq> {}"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2685	using assms B affine_hull_nonempty[of V] by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2686	ultimately have "L = Lb"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2687	using assms affine_parallel_subspace[of "affine hull B"] affine_affine_hull[of B] B
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2688	by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2689	then have "dim L = dim Lb"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2690	by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2691	moreover have "card B - 1 = dim Lb" and "finite B"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2692	using Lb_def aff_dim_parallel_subspace_aux a B by auto
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2693	ultimately show ?thesis
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2694	using B `B \<noteq> {}` card_gt_0_iff[of B] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2695	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2696
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2697	lemma aff_independent_finite:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2698	fixes B :: "'n::euclidean_space set"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2699	assumes "\<not> affine_dependent B"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2700	shows "finite B"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2701	proof -
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2702	{
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2703	assume "B \<noteq> {}"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2704	then obtain a where "a \<in> B" by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2705	then have ?thesis
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2706	using aff_dim_parallel_subspace_aux assms by auto
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2707	}
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2708	then show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2709	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2710
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2711	lemma independent_finite:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2712	fixes B :: "'n::euclidean_space set"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2713	assumes "independent B"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2714	shows "finite B"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2715	using affine_dependent_imp_dependent[of B] aff_independent_finite[of B] assms
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2716	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2717
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2718	lemma subspace_dim_equal:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2719	assumes "subspace (S :: ('n::euclidean_space) set)"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2720	and "subspace T"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2721	and "S \<subseteq> T"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2722	and "dim S \<ge> dim T"
53302 98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2723	shows "S = T"
98fdf6c34142 tuned proofs; wenzelm parents: 53077 diff changeset	2724	proof -
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2725	obtain B where B: "B \<le> S" "independent B \<and> S \<subseteq> span B" "card B = dim S"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2726	using basis_exists[of S] by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2727	then have "span B \<subseteq> S"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2728	using span_mono[of B S] span_eq[of S] assms by metis
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2729	then have "span B = S"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2730	using B by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2731	have "dim S = dim T"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2732	using assms dim_subset[of S T] by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2733	then have "T \<subseteq> span B"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2734	using card_eq_dim[of B T] B independent_finite assms by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2735	then show ?thesis
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2736	using assms `span B = S` by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2737	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2738
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	2739	lemma span_substd_basis:
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	2740	assumes d: "d \<subseteq> Basis"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2741	shows "span d = {x. \<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x\<bullet>i = 0}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2742	(is "_ = ?B")
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2743	proof -
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2744	have "d \<subseteq> ?B"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2745	using d by (auto simp: inner_Basis)
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2746	moreover have s: "subspace ?B"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2747	using subspace_substandard[of "\<lambda>i. i \<notin> d"] .
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2748	ultimately have "span d \<subseteq> ?B"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2749	using span_mono[of d "?B"] span_eq[of "?B"] by blast
53374 a14d2a854c02 tuned proofs -- clarified flow of facts wrt. calculation; wenzelm parents: 53348 diff changeset	2750	moreover have *: "card d \<le> dim (span d)"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2751	using independent_card_le_dim[of d "span d"] independent_substdbasis[OF assms] span_inc[of d]
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2752	by auto
53374 a14d2a854c02 tuned proofs -- clarified flow of facts wrt. calculation; wenzelm parents: 53348 diff changeset	2753	moreover from * have "dim ?B \<le> dim (span d)"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2754	using dim_substandard[OF assms] by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2755	ultimately show ?thesis
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2756	using s subspace_dim_equal[of "span d" "?B"] subspace_span[of d] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2757	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2758
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2759	lemma basis_to_substdbasis_subspace_isomorphism:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2760	fixes B :: "'a::euclidean_space set"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2761	assumes "independent B"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2762	shows "\<exists>f d::'a set. card d = card B \<and> linear f \<and> f ` B = d \<and>
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2763	f ` span B = {x. \<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x \<bullet> i = 0} \<and> inj_on f (span B) \<and> d \<subseteq> Basis"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2764	proof -
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2765	have B: "card B = dim B"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2766	using dim_unique[of B B "card B"] assms span_inc[of B] by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2767	have "dim B \<le> card (Basis :: 'a set)"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2768	using dim_subset_UNIV[of B] by simp
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2769	from ex_card[OF this] obtain d :: "'a set" where d: "d \<subseteq> Basis" and t: "card d = dim B"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2770	by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2771	let ?t = "{x::'a::euclidean_space. \<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x\<bullet>i = 0}"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2772	have "\<exists>f. linear f \<and> f ` B = d \<and> f ` span B = ?t \<and> inj_on f (span B)"
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	2773	apply (rule basis_to_basis_subspace_isomorphism[of "span B" ?t B "d"])
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2774	apply (rule subspace_span)
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2775	apply (rule subspace_substandard)
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2776	defer
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2777	apply (rule span_inc)
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2778	apply (rule assms)
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2779	defer
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2780	unfolding dim_span[of B]
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2781	apply(rule B)
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2782	unfolding span_substd_basis[OF d, symmetric]
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2783	apply (rule span_inc)
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2784	apply (rule independent_substdbasis[OF d])
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2785	apply rule
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2786	apply assumption
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2787	unfolding t[symmetric] span_substd_basis[OF d] dim_substandard[OF d]
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2788	apply auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2789	done
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	2790	with t `card B = dim B` d show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2791	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2792
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2793	lemma aff_dim_empty:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2794	fixes S :: "'n::euclidean_space set"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2795	shows "S = {} \<longleftrightarrow> aff_dim S = -1"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2796	proof -
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2797	obtain B where *: "affine hull B = affine hull S"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2798	and "\<not> affine_dependent B"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2799	and "int (card B) = aff_dim S + 1"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2800	using aff_dim_basis_exists by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2801	moreover
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2802	from * have "S = {} \<longleftrightarrow> B = {}"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2803	using affine_hull_nonempty[of B] affine_hull_nonempty[of S] by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2804	ultimately show ?thesis
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2805	using aff_independent_finite[of B] card_gt_0_iff[of B] by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2806	qed
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2807
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2808	lemma aff_dim_affine_hull: "aff_dim (affine hull S) = aff_dim S"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2809	unfolding aff_dim_def using hull_hull[of _ S] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2810
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2811	lemma aff_dim_affine_hull2:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2812	assumes "affine hull S = affine hull T"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2813	shows "aff_dim S = aff_dim T"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2814	unfolding aff_dim_def using assms by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2815
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	2816	lemma aff_dim_unique:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2817	fixes B V :: "'n::euclidean_space set"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2818	assumes "affine hull B = affine hull V \<and> \<not> affine_dependent B"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2819	shows "of_nat (card B) = aff_dim V + 1"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2820	proof (cases "B = {}")
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2821	case True
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2822	then have "V = {}"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2823	using affine_hull_nonempty[of V] affine_hull_nonempty[of B] assms
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2824	by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2825	then have "aff_dim V = (-1::int)"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2826	using aff_dim_empty by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2827	then show ?thesis
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2828	using `B = {}` by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2829	next
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2830	case False
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2831	then obtain a where a: "a \<in> B" by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2832	def Lb \<equiv> "span ((\<lambda>x. -a+x) ` (B-{a}))"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2833	have "affine_parallel (affine hull B) Lb"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2834	using Lb_def affine_hull_span2[of a B] a
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2835	affine_parallel_commut[of "Lb" "(affine hull B)"]
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2836	unfolding affine_parallel_def by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2837	moreover have "subspace Lb"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2838	using Lb_def subspace_span by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2839	ultimately have "aff_dim B = int(dim Lb)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2840	using aff_dim_parallel_subspace[of B Lb] `B \<noteq> {}` by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2841	moreover have "(card B) - 1 = dim Lb" "finite B"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	2842	using Lb_def aff_dim_parallel_subspace_aux a assms by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2843	ultimately have "of_nat (card B) = aff_dim B + 1"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2844	using `B \<noteq> {}` card_gt_0_iff[of B] by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2845	then show ?thesis
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2846	using aff_dim_affine_hull2 assms by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2847	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2848
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	2849	lemma aff_dim_affine_independent:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2850	fixes B :: "'n::euclidean_space set"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2851	assumes "\<not> affine_dependent B"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2852	shows "of_nat (card B) = aff_dim B + 1"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2853	using aff_dim_unique[of B B] assms by auto
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2854
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	2855	lemma aff_dim_sing:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2856	fixes a :: "'n::euclidean_space"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2857	shows "aff_dim {a} = 0"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2858	using aff_dim_affine_independent[of "{a}"] affine_independent_sing by auto
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2859
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2860	lemma aff_dim_inner_basis_exists:
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	2861	fixes V :: "('n::euclidean_space) set"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2862	shows "\<exists>B. B \<subseteq> V \<and> affine hull B = affine hull V \<and>
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2863	\<not> affine_dependent B \<and> of_nat (card B) = aff_dim V + 1"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2864	proof -
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2865	obtain B where B: "\<not> affine_dependent B" "B \<subseteq> V" "affine hull B = affine hull V"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2866	using affine_basis_exists[of V] by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2867	then have "of_nat(card B) = aff_dim V+1" using aff_dim_unique by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2868	with B show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2869	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2870
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2871	lemma aff_dim_le_card:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2872	fixes V :: "'n::euclidean_space set"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2873	assumes "finite V"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2874	shows "aff_dim V \<le> of_nat (card V) - 1"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2875	proof -
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2876	obtain B where B: "B \<subseteq> V" "of_nat (card B) = aff_dim V + 1"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2877	using aff_dim_inner_basis_exists[of V] by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2878	then have "card B \<le> card V"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2879	using assms card_mono by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2880	with B show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2881	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2882
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2883	lemma aff_dim_parallel_eq:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2884	fixes S T :: "'n::euclidean_space set"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2885	assumes "affine_parallel (affine hull S) (affine hull T)"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2886	shows "aff_dim S = aff_dim T"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2887	proof -
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2888	{
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2889	assume "T \<noteq> {}" "S \<noteq> {}"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2890	then obtain L where L: "subspace L \<and> affine_parallel (affine hull T) L"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2891	using affine_parallel_subspace[of "affine hull T"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2892	affine_affine_hull[of T] affine_hull_nonempty
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2893	by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2894	then have "aff_dim T = int (dim L)"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2895	using aff_dim_parallel_subspace `T \<noteq> {}` by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2896	moreover have *: "subspace L \<and> affine_parallel (affine hull S) L"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2897	using L affine_parallel_assoc[of "affine hull S" "affine hull T" L] assms by auto
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2898	moreover from * have "aff_dim S = int (dim L)"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2899	using aff_dim_parallel_subspace `S \<noteq> {}` by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2900	ultimately have ?thesis by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2901	}
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2902	moreover
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2903	{
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2904	assume "S = {}"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2905	then have "S = {}" and "T = {}"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2906	using assms affine_hull_nonempty
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2907	unfolding affine_parallel_def
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2908	by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2909	then have ?thesis using aff_dim_empty by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2910	}
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2911	moreover
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2912	{
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2913	assume "T = {}"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2914	then have "S = {}" and "T = {}"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2915	using assms affine_hull_nonempty
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2916	unfolding affine_parallel_def
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2917	by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2918	then have ?thesis
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2919	using aff_dim_empty by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2920	}
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2921	ultimately show ?thesis by blast
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2922	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2923
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2924	lemma aff_dim_translation_eq:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2925	fixes a :: "'n::euclidean_space"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2926	shows "aff_dim ((\<lambda>x. a + x) ` S) = aff_dim S"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2927	proof -
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2928	have "affine_parallel (affine hull S) (affine hull ((\<lambda>x. a + x) ` S))"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2929	unfolding affine_parallel_def
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2930	apply (rule exI[of _ "a"])
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2931	using affine_hull_translation[of a S]
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2932	apply auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2933	done
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2934	then show ?thesis
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2935	using aff_dim_parallel_eq[of S "(\<lambda>x. a + x) ` S"] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2936	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2937
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2938	lemma aff_dim_affine:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2939	fixes S L :: "'n::euclidean_space set"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2940	assumes "S \<noteq> {}"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2941	and "affine S"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2942	and "subspace L"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2943	and "affine_parallel S L"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2944	shows "aff_dim S = int (dim L)"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2945	proof -
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2946	have *: "affine hull S = S"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2947	using assms affine_hull_eq[of S] by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2948	then have "affine_parallel (affine hull S) L"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2949	using assms by (simp add: *)
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2950	then show ?thesis
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2951	using assms aff_dim_parallel_subspace[of S L] by blast
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2952	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2953
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2954	lemma dim_affine_hull:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2955	fixes S :: "'n::euclidean_space set"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2956	shows "dim (affine hull S) = dim S"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2957	proof -
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2958	have "dim (affine hull S) \<ge> dim S"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2959	using dim_subset by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2960	moreover have "dim (span S) \<ge> dim (affine hull S)"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2961	using dim_subset affine_hull_subset_span by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2962	moreover have "dim (span S) = dim S"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2963	using dim_span by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2964	ultimately show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2965	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2966
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2967	lemma aff_dim_subspace:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2968	fixes S :: "'n::euclidean_space set"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2969	assumes "S \<noteq> {}"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2970	and "subspace S"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2971	shows "aff_dim S = int (dim S)"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2972	using aff_dim_affine[of S S] assms subspace_imp_affine[of S] affine_parallel_reflex[of S]
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2973	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2974
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2975	lemma aff_dim_zero:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2976	fixes S :: "'n::euclidean_space set"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2977	assumes "0 \<in> affine hull S"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2978	shows "aff_dim S = int (dim S)"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2979	proof -
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2980	have "subspace (affine hull S)"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2981	using subspace_affine[of "affine hull S"] affine_affine_hull assms
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2982	by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2983	then have "aff_dim (affine hull S) = int (dim (affine hull S))"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2984	using assms aff_dim_subspace[of "affine hull S"] by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2985	then show ?thesis
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2986	using aff_dim_affine_hull[of S] dim_affine_hull[of S]
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2987	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2988	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2989
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2990	lemma aff_dim_univ: "aff_dim (UNIV :: 'n::euclidean_space set) = int(DIM('n))"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2991	using aff_dim_subspace[of "(UNIV :: 'n::euclidean_space set)"]
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2992	dim_UNIV[where 'a="'n::euclidean_space"]
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2993	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2994
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	2995	lemma aff_dim_geq:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2996	fixes V :: "'n::euclidean_space set"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2997	shows "aff_dim V \<ge> -1"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	2998	proof -
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	2999	obtain B where "affine hull B = affine hull V"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3000	and "\<not> affine_dependent B"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3001	and "int (card B) = aff_dim V + 1"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3002	using aff_dim_basis_exists by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3003	then show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3004	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3005
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3006	lemma independent_card_le_aff_dim:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3007	fixes B :: "'n::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3008	assumes "B \<subseteq> V"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3009	assumes "\<not> affine_dependent B"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3010	shows "int (card B) \<le> aff_dim V + 1"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3011	proof (cases "B = {}")
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3012	case True
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3013	then have "-1 \<le> aff_dim V"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3014	using aff_dim_geq by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3015	with True show ?thesis by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3016	next
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3017	case False
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3018	then obtain T where T: "\<not> affine_dependent T \<and> B \<subseteq> T \<and> T \<subseteq> V \<and> affine hull T = affine hull V"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3019	using assms extend_to_affine_basis[of B V] by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3020	then have "of_nat (card T) = aff_dim V + 1"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3021	using aff_dim_unique by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3022	then show ?thesis
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3023	using T card_mono[of T B] aff_independent_finite[of T] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3024	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3025
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3026	lemma aff_dim_subset:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3027	fixes S T :: "'n::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3028	assumes "S \<subseteq> T"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3029	shows "aff_dim S \<le> aff_dim T"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3030	proof -
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3031	obtain B where B: "\<not> affine_dependent B" "B \<subseteq> S" "affine hull B = affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3032	"of_nat (card B) = aff_dim S + 1"
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3033	using aff_dim_inner_basis_exists[of S] by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3034	then have "int (card B) \<le> aff_dim T + 1"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3035	using assms independent_card_le_aff_dim[of B T] by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3036	with B show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3037	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3038
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3039	lemma aff_dim_subset_univ:
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3040	fixes S :: "'n::euclidean_space set"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3041	shows "aff_dim S \<le> int (DIM('n))"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3042	proof -
53339 0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3043	have "aff_dim (UNIV :: 'n::euclidean_space set) = int(DIM('n))"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3044	using aff_dim_univ by auto
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3045	then show "aff_dim (S:: 'n::euclidean_space set) \<le> int(DIM('n))"
0dc28fd72c7d tuned proofs; wenzelm parents: 53333 diff changeset	3046	using assms aff_dim_subset[of S "(UNIV :: ('n::euclidean_space) set)"] subset_UNIV by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3047	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3048
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3049	lemma affine_dim_equal:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3050	fixes S :: "'n::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3051	assumes "affine S" "affine T" "S \<noteq> {}" "S \<subseteq> T" "aff_dim S = aff_dim T"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3052	shows "S = T"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3053	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3054	obtain a where "a \<in> S" using assms by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3055	then have "a \<in> T" using assms by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3056	def LS \<equiv> "{y. \<exists>x \<in> S. (-a) + x = y}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3057	then have ls: "subspace LS" "affine_parallel S LS"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3058	using assms parallel_subspace_explicit[of S a LS] `a \<in> S` by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3059	then have h1: "int(dim LS) = aff_dim S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3060	using assms aff_dim_affine[of S LS] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3061	have "T \<noteq> {}" using assms by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3062	def LT \<equiv> "{y. \<exists>x \<in> T. (-a) + x = y}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3063	then have lt: "subspace LT \<and> affine_parallel T LT"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3064	using assms parallel_subspace_explicit[of T a LT] `a \<in> T` by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3065	then have "int(dim LT) = aff_dim T"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3066	using assms aff_dim_affine[of T LT] `T \<noteq> {}` by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3067	then have "dim LS = dim LT"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3068	using h1 assms by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3069	moreover have "LS \<le> LT"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3070	using LS_def LT_def assms by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3071	ultimately have "LS = LT"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3072	using subspace_dim_equal[of LS LT] ls lt by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3073	moreover have "S = {x. \<exists>y \<in> LS. a+y=x}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3074	using LS_def by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3075	moreover have "T = {x. \<exists>y \<in> LT. a+y=x}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3076	using LT_def by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3077	ultimately show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3078	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3079
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3080	lemma affine_hull_univ:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3081	fixes S :: "'n::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3082	assumes "aff_dim S = int(DIM('n))"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3083	shows "affine hull S = (UNIV :: ('n::euclidean_space) set)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3084	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3085	have "S \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3086	using assms aff_dim_empty[of S] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3087	have h0: "S \<subseteq> affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3088	using hull_subset[of S _] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3089	have h1: "aff_dim (UNIV :: ('n::euclidean_space) set) = aff_dim S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3090	using aff_dim_univ assms by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3091	then have h2: "aff_dim (affine hull S) \<le> aff_dim (UNIV :: ('n::euclidean_space) set)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3092	using aff_dim_subset_univ[of "affine hull S"] assms h0 by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3093	have h3: "aff_dim S \<le> aff_dim (affine hull S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3094	using h0 aff_dim_subset[of S "affine hull S"] assms by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3095	then have h4: "aff_dim (affine hull S) = aff_dim (UNIV :: ('n::euclidean_space) set)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3096	using h0 h1 h2 by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3097	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3098	using affine_dim_equal[of "affine hull S" "(UNIV :: ('n::euclidean_space) set)"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3099	affine_affine_hull[of S] affine_UNIV assms h4 h0 `S \<noteq> {}`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3100	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3101	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3102
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3103	lemma aff_dim_convex_hull:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3104	fixes S :: "'n::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3105	shows "aff_dim (convex hull S) = aff_dim S"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3106	using aff_dim_affine_hull[of S] convex_hull_subset_affine_hull[of S]
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3107	hull_subset[of S "convex"] aff_dim_subset[of S "convex hull S"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3108	aff_dim_subset[of "convex hull S" "affine hull S"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3109	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3110
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3111	lemma aff_dim_cball:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3112	fixes a :: "'n::euclidean_space"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3113	assumes "e > 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3114	shows "aff_dim (cball a e) = int (DIM('n))"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3115	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3116	have "(\<lambda>x. a + x) ` (cball 0 e) \<subseteq> cball a e"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3117	unfolding cball_def dist_norm by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3118	then have "aff_dim (cball (0 :: 'n::euclidean_space) e) \<le> aff_dim (cball a e)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3119	using aff_dim_translation_eq[of a "cball 0 e"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3120	aff_dim_subset[of "op + a ` cball 0 e" "cball a e"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3121	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3122	moreover have "aff_dim (cball (0 :: 'n::euclidean_space) e) = int (DIM('n))"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3123	using hull_inc[of "(0 :: 'n::euclidean_space)" "cball 0 e"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3124	centre_in_cball[of "(0 :: 'n::euclidean_space)"] assms
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3125	by (simp add: dim_cball[of e] aff_dim_zero[of "cball 0 e"])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3126	ultimately show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3127	using aff_dim_subset_univ[of "cball a e"] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3128	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3129
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3130	lemma aff_dim_open:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3131	fixes S :: "'n::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3132	assumes "open S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3133	and "S \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3134	shows "aff_dim S = int (DIM('n))"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3135	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3136	obtain x where "x \<in> S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3137	using assms by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3138	then obtain e where e: "e > 0" "cball x e \<subseteq> S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3139	using open_contains_cball[of S] assms by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3140	then have "aff_dim (cball x e) \<le> aff_dim S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3141	using aff_dim_subset by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3142	with e show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3143	using aff_dim_cball[of e x] aff_dim_subset_univ[of S] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3144	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3145
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3146	lemma low_dim_interior:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3147	fixes S :: "'n::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3148	assumes "\<not> aff_dim S = int (DIM('n))"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3149	shows "interior S = {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3150	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3151	have "aff_dim(interior S) \<le> aff_dim S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3152	using interior_subset aff_dim_subset[of "interior S" S] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3153	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3154	using aff_dim_open[of "interior S"] aff_dim_subset_univ[of S] assms by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3155	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3156
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	3157	subsection {* Relative interior of a set *}
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3158
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3159	definition "rel_interior S =
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3160	{x. \<exists>T. openin (subtopology euclidean (affine hull S)) T \<and> x \<in> T \<and> T \<subseteq> S}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3161
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3162	lemma rel_interior:
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3163	"rel_interior S = {x \<in> S. \<exists>T. open T \<and> x \<in> T \<and> T \<inter> affine hull S \<subseteq> S}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3164	unfolding rel_interior_def[of S] openin_open[of "affine hull S"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3165	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3166	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3167	fix x T
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3168	assume *: "x \<in> S" "open T" "x \<in> T" "T \<inter> affine hull S \<subseteq> S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3169	then have **: "x \<in> T \<inter> affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3170	using hull_inc by auto
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	3171	show "\<exists>Tb. (\<exists>Ta. open Ta \<and> Tb = affine hull S \<inter> Ta) \<and> x \<in> Tb \<and> Tb \<subseteq> S"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	3172	apply (rule_tac x = "T \<inter> (affine hull S)" in exI)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3173	using * **
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3174	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3175	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3176	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3177
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3178	lemma mem_rel_interior: "x \<in> rel_interior S \<longleftrightarrow> (\<exists>T. open T \<and> x \<in> T \<inter> S \<and> T \<inter> affine hull S \<subseteq> S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3179	by (auto simp add: rel_interior)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3180
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3181	lemma mem_rel_interior_ball:
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3182	"x \<in> rel_interior S \<longleftrightarrow> x \<in> S \<and> (\<exists>e. e > 0 \<and> ball x e \<inter> affine hull S \<subseteq> S)"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3183	apply (simp add: rel_interior, safe)
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3184	apply (force simp add: open_contains_ball)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3185	apply (rule_tac x = "ball x e" in exI)
44457 d366fa5551ef declare euclidean_simps [simp] at the point they are proved; huffman parents: 44365 diff changeset	3186	apply simp
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3187	done
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3188
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3189	lemma rel_interior_ball:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3190	"rel_interior S = {x \<in> S. \<exists>e. e > 0 \<and> ball x e \<inter> affine hull S \<subseteq> S}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3191	using mem_rel_interior_ball [of _ S] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3192
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3193	lemma mem_rel_interior_cball:
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3194	"x \<in> rel_interior S \<longleftrightarrow> x \<in> S \<and> (\<exists>e. e > 0 \<and> cball x e \<inter> affine hull S \<subseteq> S)"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3195	apply (simp add: rel_interior, safe)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3196	apply (force simp add: open_contains_cball)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3197	apply (rule_tac x = "ball x e" in exI)
44457 d366fa5551ef declare euclidean_simps [simp] at the point they are proved; huffman parents: 44365 diff changeset	3198	apply (simp add: subset_trans [OF ball_subset_cball])
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3199	apply auto
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3200	done
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3201
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3202	lemma rel_interior_cball:
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3203	"rel_interior S = {x \<in> S. \<exists>e. e > 0 \<and> cball x e \<inter> affine hull S \<subseteq> S}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3204	using mem_rel_interior_cball [of _ S] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3205
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3206	lemma rel_interior_empty: "rel_interior {} = {}"
8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3207	by (auto simp add: rel_interior_def)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3208
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3209	lemma affine_hull_sing: "affine hull {a :: 'n::euclidean_space} = {a}"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3210	by (metis affine_hull_eq affine_sing)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3211
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3212	lemma rel_interior_sing: "rel_interior {a :: 'n::euclidean_space} = {a}"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3213	unfolding rel_interior_ball affine_hull_sing
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3214	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3215	apply (rule_tac x = "1 :: real" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3216	apply simp
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3217	done
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3218
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3219	lemma subset_rel_interior:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3220	fixes S T :: "'n::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3221	assumes "S \<subseteq> T"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3222	and "affine hull S = affine hull T"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3223	shows "rel_interior S \<subseteq> rel_interior T"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3224	using assms by (auto simp add: rel_interior_def)
8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3225
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3226	lemma rel_interior_subset: "rel_interior S \<subseteq> S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3227	by (auto simp add: rel_interior_def)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3228
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3229	lemma rel_interior_subset_closure: "rel_interior S \<subseteq> closure S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3230	using rel_interior_subset by (auto simp add: closure_def)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3231
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3232	lemma interior_subset_rel_interior: "interior S \<subseteq> rel_interior S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3233	by (auto simp add: rel_interior interior_def)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3234
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3235	lemma interior_rel_interior:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3236	fixes S :: "'n::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3237	assumes "aff_dim S = int(DIM('n))"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3238	shows "rel_interior S = interior S"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3239	proof -
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3240	have "affine hull S = UNIV"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3241	using assms affine_hull_univ[of S] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3242	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3243	unfolding rel_interior interior_def by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3244	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3245
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3246	lemma rel_interior_open:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3247	fixes S :: "'n::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3248	assumes "open S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3249	shows "rel_interior S = S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3250	by (metis assms interior_eq interior_subset_rel_interior rel_interior_subset set_eq_subset)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3251
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3252	lemma interior_rel_interior_gen:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3253	fixes S :: "'n::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3254	shows "interior S = (if aff_dim S = int(DIM('n)) then rel_interior S else {})"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3255	by (metis interior_rel_interior low_dim_interior)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3256
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3257	lemma rel_interior_univ:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3258	fixes S :: "'n::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3259	shows "rel_interior (affine hull S) = affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3260	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3261	have *: "rel_interior (affine hull S) \<subseteq> affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3262	using rel_interior_subset by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3263	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3264	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3265	assume x: "x \<in> affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3266	def e \<equiv> "1::real"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3267	then have "e > 0" "ball x e \<inter> affine hull (affine hull S) \<subseteq> affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3268	using hull_hull[of _ S] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3269	then have "x \<in> rel_interior (affine hull S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3270	using x rel_interior_ball[of "affine hull S"] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3271	}
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3272	then show ?thesis using * by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3273	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3274
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3275	lemma rel_interior_univ2: "rel_interior (UNIV :: ('n::euclidean_space) set) = UNIV"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3276	by (metis open_UNIV rel_interior_open)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3277
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3278	lemma rel_interior_convex_shrink:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3279	fixes S :: "'a::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3280	assumes "convex S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3281	and "c \<in> rel_interior S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3282	and "x \<in> S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3283	and "0 < e"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3284	and "e \<le> 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3285	shows "x - e *\<^sub>R (x - c) \<in> rel_interior S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3286	proof -
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	3287	obtain d where "d > 0" and d: "ball c d \<inter> affine hull S \<subseteq> S"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3288	using assms(2) unfolding mem_rel_interior_ball by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3289	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3290	fix y
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3291	assume as: "dist (x - e \<^sub>R (x - c)) y < e d" "y \<in> affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3292	have : "y = (1 - (1 - e)) \<^sub>R ((1 / e) \<^sub>R y - ((1 - e) / e) \<^sub>R x) + (1 - e) *\<^sub>R x"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3293	using `e > 0` by (auto simp add: scaleR_left_diff_distrib scaleR_right_diff_distrib)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3294	have "x \<in> affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3295	using assms hull_subset[of S] by auto
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3296	moreover have "1 / e + - ((1 - e) / e) = 1"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3297	using `e > 0` left_diff_distrib[of "1" "(1-e)" "1/e"] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3298	ultimately have *: "(1 / e) \<^sub>R y - ((1 - e) / e) *\<^sub>R x \<in> affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3299	using as affine_affine_hull[of S] mem_affine[of "affine hull S" y x "(1 / e)" "-((1 - e) / e)"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3300	by (simp add: algebra_simps)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3301	have "dist c ((1 / e) \<^sub>R y - ((1 - e) / e) \<^sub>R x) = abs(1/e) * norm (e \<^sub>R c - y + (1 - e) \<^sub>R x)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3302	unfolding dist_norm norm_scaleR[symmetric]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3303	apply (rule arg_cong[where f=norm])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3304	using `e > 0`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3305	apply (auto simp add: euclidean_eq_iff[where 'a='a] field_simps inner_simps)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3306	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3307	also have "\<dots> = abs (1/e) * norm (x - e *\<^sub>R (x - c) - y)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3308	by (auto intro!:arg_cong[where f=norm] simp add: algebra_simps)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3309	also have "\<dots> < d"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3310	using as[unfolded dist_norm] and `e > 0`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3311	by (auto simp add:pos_divide_less_eq[OF `e > 0`] mult_commute)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3312	finally have "y \<in> S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3313	apply (subst *)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3314	apply (rule assms(1)[unfolded convex_alt,rule_format])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3315	apply (rule d[unfolded subset_eq,rule_format])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3316	unfolding mem_ball
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3317	using assms(3-5) **
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3318	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3319	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3320	}
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3321	then have "ball (x - e \<^sub>R (x - c)) (ed) \<inter> affine hull S \<subseteq> S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3322	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3323	moreover have "e * d > 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3324	using `e > 0` `d > 0` by (rule mult_pos_pos)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3325	moreover have c: "c \<in> S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3326	using assms rel_interior_subset by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3327	moreover from c have "x - e *\<^sub>R (x - c) \<in> S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3328	using mem_convex[of S x c e]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3329	apply (simp add: algebra_simps)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3330	using assms
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3331	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3332	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3333	ultimately show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3334	using mem_rel_interior_ball[of "x - e *\<^sub>R (x - c)" S] `e > 0` by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3335	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3336
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3337	lemma interior_real_semiline:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3338	fixes a :: real
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3339	shows "interior {a..} = {a<..}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3340	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3341	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3342	fix y
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3343	assume "a < y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3344	then have "y \<in> interior {a..}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3345	apply (simp add: mem_interior)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3346	apply (rule_tac x="(y-a)" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3347	apply (auto simp add: dist_norm)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3348	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3349	}
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3350	moreover
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3351	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3352	fix y
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3353	assume "y \<in> interior {a..}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3354	then obtain e where e: "e > 0" "cball y e \<subseteq> {a..}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3355	using mem_interior_cball[of y "{a..}"] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3356	moreover from e have "y - e \<in> cball y e"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3357	by (auto simp add: cball_def dist_norm)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3358	ultimately have "a \<le> y - e" by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3359	then have "a < y" using e by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3360	}
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3361	ultimately show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3362	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3363
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	3364	lemma rel_interior_real_box:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3365	fixes a b :: real
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3366	assumes "a < b"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	3367	shows "rel_interior {a .. b} = {a <..< b}"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3368	proof -
54775 2d3df8633dad prefer box over greaterThanLessThan on euclidean_space immler parents: 54465 diff changeset	3369	have "box a b \<noteq> {}"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3370	using assms
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3371	unfolding set_eq_iff
56189 c4daa97ac57a removed dependencies on theory Ordered_Euclidean_Space immler parents: 56188 diff changeset	3372	by (auto intro!: exI[of _ "(a + b) / 2"] simp: box_def)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3373	then show ?thesis
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	3374	using interior_rel_interior_gen[of "cbox a b", symmetric]
0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	3375	by (simp split: split_if_asm del: box_real add: box_real[symmetric] interior_cbox)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3376	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3377
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3378	lemma rel_interior_real_semiline:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3379	fixes a :: real
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3380	shows "rel_interior {a..} = {a<..}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3381	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3382	have *: "{a<..} \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3383	unfolding set_eq_iff by (auto intro!: exI[of _ "a + 1"])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3384	then show ?thesis using interior_real_semiline interior_rel_interior_gen[of "{a..}"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3385	by (auto split: split_if_asm)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3386	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3387
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	3388	subsubsection {* Relative open sets *}
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3389
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3390	definition "rel_open S \<longleftrightarrow> rel_interior S = S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3391
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3392	lemma rel_open: "rel_open S \<longleftrightarrow> openin (subtopology euclidean (affine hull S)) S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3393	unfolding rel_open_def rel_interior_def
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3394	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3395	using openin_subopen[of "subtopology euclidean (affine hull S)" S]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3396	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3397	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3398
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3399	lemma opein_rel_interior: "openin (subtopology euclidean (affine hull S)) (rel_interior S)"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3400	apply (simp add: rel_interior_def)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3401	apply (subst openin_subopen)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3402	apply blast
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3403	done
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3404
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3405	lemma affine_rel_open:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3406	fixes S :: "'n::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3407	assumes "affine S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3408	shows "rel_open S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3409	unfolding rel_open_def
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3410	using assms rel_interior_univ[of S] affine_hull_eq[of S]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3411	by metis
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3412
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3413	lemma affine_closed:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3414	fixes S :: "'n::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3415	assumes "affine S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3416	shows "closed S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3417	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3418	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3419	assume "S \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3420	then obtain L where L: "subspace L" "affine_parallel S L"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3421	using assms affine_parallel_subspace[of S] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3422	then obtain a where a: "S = (op + a ` L)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3423	using affine_parallel_def[of L S] affine_parallel_commut by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3424	from L have "closed L" using closed_subspace by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3425	then have "closed S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3426	using closed_translation a by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3427	}
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3428	then show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3429	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3430
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3431	lemma closure_affine_hull:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3432	fixes S :: "'n::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3433	shows "closure S \<subseteq> affine hull S"
44524 04ad69081646 generalize some lemmas huffman parents: 44523 diff changeset	3434	by (intro closure_minimal hull_subset affine_closed affine_affine_hull)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3435
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3436	lemma closure_same_affine_hull:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3437	fixes S :: "'n::euclidean_space set"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3438	shows "affine hull (closure S) = affine hull S"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3439	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3440	have "affine hull (closure S) \<subseteq> affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3441	using hull_mono[of "closure S" "affine hull S" "affine"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3442	closure_affine_hull[of S] hull_hull[of "affine" S]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3443	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3444	moreover have "affine hull (closure S) \<supseteq> affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3445	using hull_mono[of "S" "closure S" "affine"] closure_subset by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3446	ultimately show ?thesis by auto
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3447	qed
8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3448
8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3449	lemma closure_aff_dim:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3450	fixes S :: "'n::euclidean_space set"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3451	shows "aff_dim (closure S) = aff_dim S"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3452	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3453	have "aff_dim S \<le> aff_dim (closure S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3454	using aff_dim_subset closure_subset by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3455	moreover have "aff_dim (closure S) \<le> aff_dim (affine hull S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3456	using aff_dim_subset closure_affine_hull by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3457	moreover have "aff_dim (affine hull S) = aff_dim S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3458	using aff_dim_affine_hull by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3459	ultimately show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3460	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3461
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3462	lemma rel_interior_closure_convex_shrink:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3463	fixes S :: "_::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3464	assumes "convex S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3465	and "c \<in> rel_interior S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3466	and "x \<in> closure S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3467	and "e > 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3468	and "e \<le> 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3469	shows "x - e *\<^sub>R (x - c) \<in> rel_interior S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3470	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3471	obtain d where "d > 0" and d: "ball c d \<inter> affine hull S \<subseteq> S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3472	using assms(2) unfolding mem_rel_interior_ball by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3473	have "\<exists>y \<in> S. norm (y - x) * (1 - e) < e * d"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3474	proof (cases "x \<in> S")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3475	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3476	then show ?thesis using `e > 0` `d > 0`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3477	apply (rule_tac bexI[where x=x])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3478	apply (auto intro!: mult_pos_pos)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3479	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3480	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3481	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3482	then have x: "x islimpt S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3483	using assms(3)[unfolded closure_def] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3484	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3485	proof (cases "e = 1")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3486	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3487	obtain y where "y \<in> S" "y \<noteq> x" "dist y x < 1"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3488	using x[unfolded islimpt_approachable,THEN spec[where x=1]] by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3489	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3490	apply (rule_tac x=y in bexI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3491	unfolding True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3492	using `d > 0`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3493	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3494	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3495	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3496	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3497	then have "0 < e * d / (1 - e)" and *: "1 - e > 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3498	using `e \<le> 1` `e > 0` `d > 0`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3499	by (auto intro!:mult_pos_pos divide_pos_pos)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3500	then obtain y where "y \<in> S" "y \<noteq> x" "dist y x < e * d / (1 - e)"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3501	using x[unfolded islimpt_approachable,THEN spec[where x="e*d / (1 - e)"]] by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3502	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3503	apply (rule_tac x=y in bexI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3504	unfolding dist_norm
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3505	using pos_less_divide_eq[OF *]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3506	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3507	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3508	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3509	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3510	then obtain y where "y \<in> S" and y: "norm (y - x) * (1 - e) < e * d"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3511	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3512	def z \<equiv> "c + ((1 - e) / e) *\<^sub>R (x - y)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3513	have : "x - e \<^sub>R (x - c) = y - e *\<^sub>R (y - z)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3514	unfolding z_def using `e > 0`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3515	by (auto simp add: scaleR_right_diff_distrib scaleR_right_distrib scaleR_left_diff_distrib)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3516	have zball: "z \<in> ball c d"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3517	using mem_ball z_def dist_norm[of c]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3518	using y and assms(4,5)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3519	by (auto simp add:field_simps norm_minus_commute)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3520	have "x \<in> affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3521	using closure_affine_hull assms by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3522	moreover have "y \<in> affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3523	using `y \<in> S` hull_subset[of S] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3524	moreover have "c \<in> affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3525	using assms rel_interior_subset hull_subset[of S] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3526	ultimately have "z \<in> affine hull S"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3527	using z_def affine_affine_hull[of S]
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3528	mem_affine_3_minus [of "affine hull S" c x y "(1 - e) / e"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3529	assms
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3530	by (auto simp add: field_simps)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3531	then have "z \<in> S" using d zball by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3532	obtain d1 where "d1 > 0" and d1: "ball z d1 \<le> ball c d"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3533	using zball open_ball[of c d] openE[of "ball c d" z] by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3534	then have "ball z d1 \<inter> affine hull S \<subseteq> ball c d \<inter> affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3535	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3536	then have "ball z d1 \<inter> affine hull S \<subseteq> S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3537	using d by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3538	then have "z \<in> rel_interior S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3539	using mem_rel_interior_ball using `d1 > 0` `z \<in> S` by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3540	then have "y - e *\<^sub>R (y - z) \<in> rel_interior S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3541	using rel_interior_convex_shrink[of S z y e] assms `y \<in> S` by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3542	then show ?thesis using * by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3543	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3544
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3545
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	3546	subsubsection{* Relative interior preserves under linear transformations *}
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3547
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3548	lemma rel_interior_translation_aux:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3549	fixes a :: "'n::euclidean_space"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3550	shows "((\<lambda>x. a + x) ` rel_interior S) \<subseteq> rel_interior ((\<lambda>x. a + x) ` S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3551	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3552	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3553	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3554	assume x: "x \<in> rel_interior S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3555	then obtain T where "open T" "x \<in> T \<inter> S" "T \<inter> affine hull S \<subseteq> S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3556	using mem_rel_interior[of x S] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3557	then have "open ((\<lambda>x. a + x) ` T)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3558	and "a + x \<in> ((\<lambda>x. a + x) ` T) \<inter> ((\<lambda>x. a + x) ` S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3559	and "((\<lambda>x. a + x) ` T) \<inter> affine hull ((\<lambda>x. a + x) ` S) \<subseteq> (\<lambda>x. a + x) ` S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3560	using affine_hull_translation[of a S] open_translation[of T a] x by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3561	then have "a + x \<in> rel_interior ((\<lambda>x. a + x) ` S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3562	using mem_rel_interior[of "a+x" "((\<lambda>x. a + x) ` S)"] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3563	}
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3564	then show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3565	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3566
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3567	lemma rel_interior_translation:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3568	fixes a :: "'n::euclidean_space"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3569	shows "rel_interior ((\<lambda>x. a + x) ` S) = (\<lambda>x. a + x) ` rel_interior S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3570	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3571	have "(\<lambda>x. (-a) + x) ` rel_interior ((\<lambda>x. a + x) ` S) \<subseteq> rel_interior S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3572	using rel_interior_translation_aux[of "-a" "(\<lambda>x. a + x) ` S"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3573	translation_assoc[of "-a" "a"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3574	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3575	then have "((\<lambda>x. a + x) ` rel_interior S) \<supseteq> rel_interior ((\<lambda>x. a + x) ` S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3576	using translation_inverse_subset[of a "rel_interior (op + a ` S)" "rel_interior S"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3577	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3578	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3579	using rel_interior_translation_aux[of a S] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3580	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3581
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3582
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3583	lemma affine_hull_linear_image:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3584	assumes "bounded_linear f"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3585	shows "f ` (affine hull s) = affine hull f ` s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3586	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3587	unfolding subset_eq ball_simps
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3588	apply (rule_tac[!] hull_induct, rule hull_inc)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3589	prefer 3
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3590	apply (erule imageE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3591	apply (rule_tac x=xa in image_eqI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3592	apply assumption
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3593	apply (rule hull_subset[unfolded subset_eq, rule_format])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3594	apply assumption
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3595	proof -
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3596	interpret f: bounded_linear f by fact
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3597	show "affine {x. f x \<in> affine hull f ` s}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3598	unfolding affine_def
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3599	by (auto simp add: f.scaleR f.add affine_affine_hull[unfolded affine_def, rule_format])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3600	show "affine {x. x \<in> f ` (affine hull s)}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3601	using affine_affine_hull[unfolded affine_def, of s]
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3602	unfolding affine_def by (auto simp add: f.scaleR [symmetric] f.add [symmetric])
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3603	qed auto
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3604
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3605
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3606	lemma rel_interior_injective_on_span_linear_image:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3607	fixes f :: "'m::euclidean_space \<Rightarrow> 'n::euclidean_space"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3608	and S :: "'m::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3609	assumes "bounded_linear f"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3610	and "inj_on f (span S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3611	shows "rel_interior (f ` S) = f ` (rel_interior S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3612	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3613	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3614	fix z
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3615	assume z: "z \<in> rel_interior (f ` S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3616	then have "z \<in> f ` S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3617	using rel_interior_subset[of "f ` S"] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3618	then obtain x where x: "x \<in> S" "f x = z" by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3619	obtain e2 where e2: "e2 > 0" "cball z e2 \<inter> affine hull (f ` S) \<subseteq> (f ` S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3620	using z rel_interior_cball[of "f ` S"] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3621	obtain K where K: "K > 0" "\<And>x. norm (f x) \<le> norm x * K"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3622	using assms Real_Vector_Spaces.bounded_linear.pos_bounded[of f] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3623	def e1 \<equiv> "1 / K"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3624	then have e1: "e1 > 0" "\<And>x. e1 * norm (f x) \<le> norm x"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3625	using K pos_le_divide_eq[of e1] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3626	def e \<equiv> "e1 * e2"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3627	then have "e > 0" using e1 e2 mult_pos_pos by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3628	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3629	fix y
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3630	assume y: "y \<in> cball x e \<inter> affine hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3631	then have h1: "f y \<in> affine hull (f ` S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3632	using affine_hull_linear_image[of f S] assms by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3633	from y have "norm (x-y) \<le> e1 * e2"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3634	using cball_def[of x e] dist_norm[of x y] e_def by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3635	moreover have "f x - f y = f (x - y)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3636	using assms linear_sub[of f x y] linear_conv_bounded_linear[of f] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3637	moreover have "e1 * norm (f (x-y)) \<le> norm (x - y)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3638	using e1 by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3639	ultimately have "e1 * norm ((f x)-(f y)) \<le> e1 * e2"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3640	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3641	then have "f y \<in> cball z e2"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3642	using cball_def[of "f x" e2] dist_norm[of "f x" "f y"] e1 x by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3643	then have "f y \<in> f ` S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3644	using y e2 h1 by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3645	then have "y \<in> S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3646	using assms y hull_subset[of S] affine_hull_subset_span
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3647	inj_on_image_mem_iff[of f "span S" S y]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3648	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3649	}
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3650	then have "z \<in> f ` (rel_interior S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3651	using mem_rel_interior_cball[of x S] `e > 0` x by auto
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3652	}
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3653	moreover
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3654	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3655	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3656	assume x: "x \<in> rel_interior S"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	3657	then obtain e2 where e2: "e2 > 0" "cball x e2 \<inter> affine hull S \<subseteq> S"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3658	using rel_interior_cball[of S] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3659	have "x \<in> S" using x rel_interior_subset by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3660	then have *: "f x \<in> f ` S" by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3661	have "\<forall>x\<in>span S. f x = 0 \<longrightarrow> x = 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3662	using assms subspace_span linear_conv_bounded_linear[of f]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3663	linear_injective_on_subspace_0[of f "span S"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3664	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3665	then obtain e1 where e1: "e1 > 0" "\<forall>x \<in> span S. e1 * norm x \<le> norm (f x)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3666	using assms injective_imp_isometric[of "span S" f]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3667	subspace_span[of S] closed_subspace[of "span S"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3668	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3669	def e \<equiv> "e1 * e2"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3670	then have "e > 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3671	using e1 e2 mult_pos_pos by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3672	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3673	fix y
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3674	assume y: "y \<in> cball (f x) e \<inter> affine hull (f ` S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3675	then have "y \<in> f ` (affine hull S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3676	using affine_hull_linear_image[of f S] assms by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3677	then obtain xy where xy: "xy \<in> affine hull S" "f xy = y" by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3678	with y have "norm (f x - f xy) \<le> e1 * e2"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3679	using cball_def[of "f x" e] dist_norm[of "f x" y] e_def by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3680	moreover have "f x - f xy = f (x - xy)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3681	using assms linear_sub[of f x xy] linear_conv_bounded_linear[of f] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3682	moreover have *: "x - xy \<in> span S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3683	using subspace_sub[of "span S" x xy] subspace_span `x \<in> S` xy
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3684	affine_hull_subset_span[of S] span_inc
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3685	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3686	moreover from * have "e1 * norm (x - xy) \<le> norm (f (x - xy))"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3687	using e1 by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3688	ultimately have "e1 * norm (x - xy) \<le> e1 * e2"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3689	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3690	then have "xy \<in> cball x e2"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3691	using cball_def[of x e2] dist_norm[of x xy] e1 by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3692	then have "y \<in> f ` S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3693	using xy e2 by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3694	}
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3695	then have "f x \<in> rel_interior (f ` S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3696	using mem_rel_interior_cball[of "(f x)" "(f ` S)"] * `e > 0` by auto
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	3697	}
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3698	ultimately show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3699	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3700
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3701	lemma rel_interior_injective_linear_image:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3702	fixes f :: "'m::euclidean_space \<Rightarrow> 'n::euclidean_space"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3703	assumes "bounded_linear f"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3704	and "inj f"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3705	shows "rel_interior (f ` S) = f ` (rel_interior S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3706	using assms rel_interior_injective_on_span_linear_image[of f S]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3707	subset_inj_on[of f "UNIV" "span S"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3708	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3709
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3710
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3711	subsection{* Some Properties of subset of standard basis *}
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3712
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3713	lemma affine_hull_substd_basis:
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3714	assumes "d \<subseteq> Basis"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3715	shows "affine hull (insert 0 d) = {x::'a::euclidean_space. \<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x\<bullet>i = 0}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3716	(is "affine hull (insert 0 ?A) = ?B")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3717	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3718	have *: "\<And>A. op + (0\<Colon>'a) ` A = A" "\<And>A. op + (- (0\<Colon>'a)) ` A = A"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3719	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3720	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3721	unfolding affine_hull_insert_span_gen span_substd_basis[OF assms,symmetric] * ..
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3722	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3723
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3724	lemma affine_hull_convex_hull: "affine hull (convex hull S) = affine hull S"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3725	by (metis Int_absorb1 Int_absorb2 convex_hull_subset_affine_hull hull_hull hull_mono hull_subset)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3726
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	3727
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3728	subsection {* Openness and compactness are preserved by convex hull operation. *}
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3729
34964 4e8be3c04d37 Replaced vec1 and dest_vec1 by abbreviation. hoelzl parents: 34915 diff changeset	3730	lemma open_convex_hull[intro]:
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3731	fixes s :: "'a::real_normed_vector set"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3732	assumes "open s"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3733	shows "open (convex hull s)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3734	unfolding open_contains_cball convex_hull_explicit
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3735	unfolding mem_Collect_eq ball_simps(8)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3736	proof (rule, rule)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3737	fix a
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3738	assume "\<exists>sa u. finite sa \<and> sa \<subseteq> s \<and> (\<forall>x\<in>sa. 0 \<le> u x) \<and> setsum u sa = 1 \<and> (\<Sum>v\<in>sa. u v *\<^sub>R v) = a"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3739	then obtain t u where obt: "finite t" "t\<subseteq>s" "\<forall>x\<in>t. 0 \<le> u x" "setsum u t = 1" "(\<Sum>v\<in>t. u v *\<^sub>R v) = a"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3740	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3741
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3742	from assms[unfolded open_contains_cball] obtain b
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3743	where b: "\<forall>x\<in>s. 0 < b x \<and> cball x (b x) \<subseteq> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3744	using bchoice[of s "\<lambda>x e. e > 0 \<and> cball x e \<subseteq> s"] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3745	have "b ` t \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3746	unfolding i_def using obt by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3747	def i \<equiv> "b ` t"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3748
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3749	show "\<exists>e > 0.
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3750	cball a e \<subseteq> {y. \<exists>sa u. finite sa \<and> sa \<subseteq> s \<and> (\<forall>x\<in>sa. 0 \<le> u x) \<and> setsum u sa = 1 \<and> (\<Sum>v\<in>sa. u v *\<^sub>R v) = y}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3751	apply (rule_tac x = "Min i" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3752	unfolding subset_eq
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3753	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3754	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3755	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3756	unfolding mem_Collect_eq
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3757	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3758	show "0 < Min i"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3759	unfolding i_def and Min_gr_iff[OF finite_imageI[OF obt(1)] `b \` t\<noteq>{}`]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3760	using b
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3761	apply simp
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3762	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3763	apply (erule_tac x=x in ballE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3764	using `t\<subseteq>s`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3765	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3766	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3767	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3768	fix y
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3769	assume "y \<in> cball a (Min i)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3770	then have y: "norm (a - y) \<le> Min i"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3771	unfolding dist_norm[symmetric] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3772	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3773	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3774	assume "x \<in> t"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3775	then have "Min i \<le> b x"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3776	unfolding i_def
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3777	apply (rule_tac Min_le)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3778	using obt(1)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3779	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3780	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3781	then have "x + (y - a) \<in> cball x (b x)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3782	using y unfolding mem_cball dist_norm by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3783	moreover from `x\<in>t` have "x \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3784	using obt(2) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3785	ultimately have "x + (y - a) \<in> s"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	3786	using y and b[THEN bspec[where x=x]] unfolding subset_eq by fast
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3787	}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3788	moreover
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3789	have *: "inj_on (\<lambda>v. v + (y - a)) t"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3790	unfolding inj_on_def by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3791	have "(\<Sum>v\<in>(\<lambda>v. v + (y - a)) ` t. u (v - (y - a))) = 1"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3792	unfolding setsum_reindex[OF *] o_def using obt(4) by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3793	moreover have "(\<Sum>v\<in>(\<lambda>v. v + (y - a)) ` t. u (v - (y - a)) *\<^sub>R v) = y"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3794	unfolding setsum_reindex[OF *] o_def using obt(4,5)
49530 7faf67b411b4 tuned; wenzelm parents: 49529 diff changeset	3795	by (simp add: setsum_addf setsum_subtractf scaleR_left.setsum[symmetric] scaleR_right_distrib)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3796	ultimately
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3797	show "\<exists>sa u. finite sa \<and> (\<forall>x\<in>sa. x \<in> s) \<and> (\<forall>x\<in>sa. 0 \<le> u x) \<and> setsum u sa = 1 \<and> (\<Sum>v\<in>sa. u v *\<^sub>R v) = y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3798	apply (rule_tac x="(\<lambda>v. v + (y - a)) ` t" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3799	apply (rule_tac x="\<lambda>v. u (v - (y - a))" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3800	using obt(1, 3)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3801	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3802	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3803	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3804	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3805
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3806	lemma compact_convex_combinations:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3807	fixes s t :: "'a::real_normed_vector set"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3808	assumes "compact s" "compact t"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3809	shows "compact { (1 - u) \<^sub>R x + u \<^sub>R y \| x y u. 0 \<le> u \<and> u \<le> 1 \<and> x \<in> s \<and> y \<in> t}"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3810	proof -
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3811	let ?X = "{0..1} \<times> s \<times> t"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3812	let ?h = "(\<lambda>z. (1 - fst z) \<^sub>R fst (snd z) + fst z \<^sub>R snd (snd z))"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3813	have : "{ (1 - u) \<^sub>R x + u *\<^sub>R y \| x y u. 0 \<le> u \<and> u \<le> 1 \<and> x \<in> s \<and> y \<in> t} = ?h ` ?X"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3814	apply (rule set_eqI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3815	unfolding image_iff mem_Collect_eq
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3816	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3817	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3818	apply (rule_tac x=u in rev_bexI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3819	apply simp
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3820	apply (erule rev_bexI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3821	apply (erule rev_bexI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3822	apply simp
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3823	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3824	done
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	3825	have "continuous_on ?X (\<lambda>z. (1 - fst z) \<^sub>R fst (snd z) + fst z \<^sub>R snd (snd z))"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3826	unfolding continuous_on by (rule ballI) (intro tendsto_intros)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3827	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3828	unfolding *
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3829	apply (rule compact_continuous_image)
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	3830	apply (intro compact_Times compact_Icc assms)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3831	done
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3832	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3833
44525 fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3834	lemma finite_imp_compact_convex_hull:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3835	fixes s :: "'a::real_normed_vector set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3836	assumes "finite s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3837	shows "compact (convex hull s)"
44525 fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3838	proof (cases "s = {}")
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3839	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3840	then show ?thesis by simp
44525 fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3841	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3842	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3843	with assms show ?thesis
44525 fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3844	proof (induct rule: finite_ne_induct)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3845	case (singleton x)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3846	show ?case by simp
44525 fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3847	next
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3848	case (insert x A)
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3849	let ?f = "\<lambda>(u, y::'a). u \<^sub>R x + (1 - u) \<^sub>R y"
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3850	let ?T = "{0..1::real} \<times> (convex hull A)"
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3851	have "continuous_on ?T ?f"
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3852	unfolding split_def continuous_on by (intro ballI tendsto_intros)
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3853	moreover have "compact ?T"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	3854	by (intro compact_Times compact_Icc insert)
44525 fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3855	ultimately have "compact (?f ` ?T)"
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3856	by (rule compact_continuous_image)
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3857	also have "?f ` ?T = convex hull (insert x A)"
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3858	unfolding convex_hull_insert [OF `A \<noteq> {}`]
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3859	apply safe
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3860	apply (rule_tac x=a in exI, simp)
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3861	apply (rule_tac x="1 - a" in exI, simp)
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3862	apply fast
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3863	apply (rule_tac x="(u, b)" in image_eqI, simp_all)
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3864	done
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3865	finally show "compact (convex hull (insert x A))" .
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3866	qed
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3867	qed
fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	3868
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3869	lemma compact_convex_hull:
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3870	fixes s :: "'a::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3871	assumes "compact s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3872	shows "compact (convex hull s)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3873	proof (cases "s = {}")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3874	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3875	then show ?thesis using compact_empty by simp
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3876	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3877	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3878	then obtain w where "w \<in> s" by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3879	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3880	unfolding caratheodory[of s]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3881	proof (induct ("DIM('a) + 1"))
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3882	case 0
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3883	have *: "{x.\<exists>sa. finite sa \<and> sa \<subseteq> s \<and> card sa \<le> 0 \<and> x \<in> convex hull sa} = {}"
36362 06475a1547cb fix lots of looping simp calls and other warnings huffman parents: 36341 diff changeset	3884	using compact_empty by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3885	from 0 show ?case unfolding * by simp
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3886	next
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3887	case (Suc n)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3888	show ?case
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3889	proof (cases "n = 0")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3890	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3891	have "{x. \<exists>t. finite t \<and> t \<subseteq> s \<and> card t \<le> Suc n \<and> x \<in> convex hull t} = s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3892	unfolding set_eq_iff and mem_Collect_eq
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3893	proof (rule, rule)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3894	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3895	assume "\<exists>t. finite t \<and> t \<subseteq> s \<and> card t \<le> Suc n \<and> x \<in> convex hull t"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3896	then obtain t where t: "finite t" "t \<subseteq> s" "card t \<le> Suc n" "x \<in> convex hull t"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3897	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3898	show "x \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3899	proof (cases "card t = 0")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3900	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3901	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3902	using t(4) unfolding card_0_eq[OF t(1)] by simp
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3903	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3904	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3905	then have "card t = Suc 0" using t(3) `n=0` by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3906	then obtain a where "t = {a}" unfolding card_Suc_eq by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3907	then show ?thesis using t(2,4) by simp
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3908	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3909	next
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3910	fix x assume "x\<in>s"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3911	then show "\<exists>t. finite t \<and> t \<subseteq> s \<and> card t \<le> Suc n \<and> x \<in> convex hull t"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3912	apply (rule_tac x="{x}" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3913	unfolding convex_hull_singleton
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3914	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3915	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3916	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3917	then show ?thesis using assms by simp
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3918	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3919	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3920	have "{x. \<exists>t. finite t \<and> t \<subseteq> s \<and> card t \<le> Suc n \<and> x \<in> convex hull t} =
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3921	{(1 - u) \<^sub>R x + u \<^sub>R y \| x y u.
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3922	0 \<le> u \<and> u \<le> 1 \<and> x \<in> s \<and> y \<in> {x. \<exists>t. finite t \<and> t \<subseteq> s \<and> card t \<le> n \<and> x \<in> convex hull t}}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3923	unfolding set_eq_iff and mem_Collect_eq
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3924	proof (rule, rule)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3925	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3926	assume "\<exists>u v c. x = (1 - c) \<^sub>R u + c \<^sub>R v \<and>
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3927	0 \<le> c \<and> c \<le> 1 \<and> u \<in> s \<and> (\<exists>t. finite t \<and> t \<subseteq> s \<and> card t \<le> n \<and> v \<in> convex hull t)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3928	then obtain u v c t where obt: "x = (1 - c) \<^sub>R u + c \<^sub>R v"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3929	"0 \<le> c \<and> c \<le> 1" "u \<in> s" "finite t" "t \<subseteq> s" "card t \<le> n" "v \<in> convex hull t"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3930	by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3931	moreover have "(1 - c) \<^sub>R u + c \<^sub>R v \<in> convex hull insert u t"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3932	apply (rule mem_convex)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3933	using obt(2) and convex_convex_hull and hull_subset[of "insert u t" convex]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3934	using obt(7) and hull_mono[of t "insert u t"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3935	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3936	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3937	ultimately show "\<exists>t. finite t \<and> t \<subseteq> s \<and> card t \<le> Suc n \<and> x \<in> convex hull t"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3938	apply (rule_tac x="insert u t" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3939	apply (auto simp add: card_insert_if)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3940	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3941	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3942	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3943	assume "\<exists>t. finite t \<and> t \<subseteq> s \<and> card t \<le> Suc n \<and> x \<in> convex hull t"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3944	then obtain t where t: "finite t" "t \<subseteq> s" "card t \<le> Suc n" "x \<in> convex hull t"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3945	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3946	show "\<exists>u v c. x = (1 - c) \<^sub>R u + c \<^sub>R v \<and>
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3947	0 \<le> c \<and> c \<le> 1 \<and> u \<in> s \<and> (\<exists>t. finite t \<and> t \<subseteq> s \<and> card t \<le> n \<and> v \<in> convex hull t)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3948	proof (cases "card t = Suc n")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3949	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3950	then have "card t \<le> n" using t(3) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3951	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3952	apply (rule_tac x=w in exI, rule_tac x=x in exI, rule_tac x=1 in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3953	using `w\<in>s` and t
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3954	apply (auto intro!: exI[where x=t])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3955	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3956	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3957	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3958	then obtain a u where au: "t = insert a u" "a\<notin>u"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3959	apply (drule_tac card_eq_SucD)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3960	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3961	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3962	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3963	proof (cases "u = {}")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3964	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3965	then have "x = a" using t(4)[unfolded au] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3966	show ?thesis unfolding `x = a`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3967	apply (rule_tac x=a in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3968	apply (rule_tac x=a in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3969	apply (rule_tac x=1 in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3970	using t and `n \<noteq> 0`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3971	unfolding au
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3972	apply (auto intro!: exI[where x="{a}"])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3973	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3974	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3975	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3976	obtain ux vx b where obt: "ux\<ge>0" "vx\<ge>0" "ux + vx = 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3977	"b \<in> convex hull u" "x = ux \<^sub>R a + vx \<^sub>R b"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3978	using t(4)[unfolded au convex_hull_insert[OF False]]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3979	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3980	have *: "1 - vx = ux" using obt(3) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3981	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3982	apply (rule_tac x=a in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3983	apply (rule_tac x=b in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3984	apply (rule_tac x=vx in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3985	using obt and t(1-3)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3986	unfolding au and * using card_insert_disjoint[OF _ au(2)]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3987	apply (auto intro!: exI[where x=u])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3988	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3989	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3990	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3991	qed
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3992	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3993	using compact_convex_combinations[OF assms Suc] by simp
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3994	qed
36362 06475a1547cb fix lots of looping simp calls and other warnings huffman parents: 36341 diff changeset	3995	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3996	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3997
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	3998
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	3999	subsection {* Extremal points of a simplex are some vertices. *}
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4000
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4001	lemma dist_increases_online:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4002	fixes a b d :: "'a::real_inner"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4003	assumes "d \<noteq> 0"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4004	shows "dist a (b + d) > dist a b \<or> dist a (b - d) > dist a b"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4005	proof (cases "inner a d - inner b d > 0")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4006	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4007	then have "0 < inner d d + (inner a d * 2 - inner b d * 2)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4008	apply (rule_tac add_pos_pos)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4009	using assms
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4010	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4011	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4012	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4013	apply (rule_tac disjI2)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4014	unfolding dist_norm and norm_eq_sqrt_inner and real_sqrt_less_iff
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4015	apply (simp add: algebra_simps inner_commute)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4016	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4017	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4018	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4019	then have "0 < inner d d + (inner b d * 2 - inner a d * 2)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4020	apply (rule_tac add_pos_nonneg)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4021	using assms
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4022	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4023	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4024	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4025	apply (rule_tac disjI1)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4026	unfolding dist_norm and norm_eq_sqrt_inner and real_sqrt_less_iff
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4027	apply (simp add: algebra_simps inner_commute)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4028	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4029	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4030
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4031	lemma norm_increases_online:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4032	fixes d :: "'a::real_inner"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4033	shows "d \<noteq> 0 \<Longrightarrow> norm (a + d) > norm a \<or> norm(a - d) > norm a"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4034	using dist_increases_online[of d a 0] unfolding dist_norm by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4035
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4036	lemma simplex_furthest_lt:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4037	fixes s :: "'a::real_inner set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4038	assumes "finite s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4039	shows "\<forall>x \<in> convex hull s. x \<notin> s \<longrightarrow> (\<exists>y \<in> convex hull s. norm (x - a) < norm(y - a))"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4040	using assms
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4041	proof induct
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4042	fix x s
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4043	assume as: "finite s" "x\<notin>s" "\<forall>x\<in>convex hull s. x \<notin> s \<longrightarrow> (\<exists>y\<in>convex hull s. norm (x - a) < norm (y - a))"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4044	show "\<forall>xa\<in>convex hull insert x s. xa \<notin> insert x s \<longrightarrow>
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4045	(\<exists>y\<in>convex hull insert x s. norm (xa - a) < norm (y - a))"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4046	proof (rule, rule, cases "s = {}")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4047	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4048	fix y
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4049	assume y: "y \<in> convex hull insert x s" "y \<notin> insert x s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4050	obtain u v b where obt: "u\<ge>0" "v\<ge>0" "u + v = 1" "b \<in> convex hull s" "y = u \<^sub>R x + v \<^sub>R b"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4051	using y(1)[unfolded convex_hull_insert[OF False]] by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4052	show "\<exists>z\<in>convex hull insert x s. norm (y - a) < norm (z - a)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4053	proof (cases "y \<in> convex hull s")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4054	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4055	then obtain z where "z \<in> convex hull s" "norm (y - a) < norm (z - a)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4056	using as(3)[THEN bspec[where x=y]] and y(2) by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4057	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4058	apply (rule_tac x=z in bexI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4059	unfolding convex_hull_insert[OF False]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4060	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4061	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4062	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4063	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4064	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4065	using obt(3)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4066	proof (cases "u = 0", case_tac[!] "v = 0")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4067	assume "u = 0" "v \<noteq> 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4068	then have "y = b" using obt by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4069	then show ?thesis using False and obt(4) by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4070	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4071	assume "u \<noteq> 0" "v = 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4072	then have "y = x" using obt by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4073	then show ?thesis using y(2) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4074	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4075	assume "u \<noteq> 0" "v \<noteq> 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4076	then obtain w where w: "w>0" "w<u" "w<v"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4077	using real_lbound_gt_zero[of u v] and obt(1,2) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4078	have "x \<noteq> b"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4079	proof
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4080	assume "x = b"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4081	then have "y = b" unfolding obt(5)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4082	using obt(3) by (auto simp add: scaleR_left_distrib[symmetric])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4083	then show False using obt(4) and False by simp
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4084	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4085	then have : "w \<^sub>R (x - b) \<noteq> 0" using w(1) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4086	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4087	using dist_increases_online[OF *, of a y]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4088	proof (elim disjE)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4089	assume "dist a y < dist a (y + w *\<^sub>R (x - b))"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4090	then have "norm (y - a) < norm ((u + w) \<^sub>R x + (v - w) \<^sub>R b - a)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4091	unfolding dist_commute[of a]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4092	unfolding dist_norm obt(5)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4093	by (simp add: algebra_simps)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4094	moreover have "(u + w) \<^sub>R x + (v - w) \<^sub>R b \<in> convex hull insert x s"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4095	unfolding convex_hull_insert[OF `s\<noteq>{}`] and mem_Collect_eq
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4096	apply (rule_tac x="u + w" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4097	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4098	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4099	apply (rule_tac x="v - w" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4100	using `u \<ge> 0` and w and obt(3,4)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4101	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4102	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4103	ultimately show ?thesis by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4104	next
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4105	assume "dist a y < dist a (y - w *\<^sub>R (x - b))"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4106	then have "norm (y - a) < norm ((u - w) \<^sub>R x + (v + w) \<^sub>R b - a)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4107	unfolding dist_commute[of a]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4108	unfolding dist_norm obt(5)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4109	by (simp add: algebra_simps)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4110	moreover have "(u - w) \<^sub>R x + (v + w) \<^sub>R b \<in> convex hull insert x s"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4111	unfolding convex_hull_insert[OF `s\<noteq>{}`] and mem_Collect_eq
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4112	apply (rule_tac x="u - w" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4113	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4114	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4115	apply (rule_tac x="v + w" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4116	using `u \<ge> 0` and w and obt(3,4)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4117	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4118	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4119	ultimately show ?thesis by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4120	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4121	qed auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4122	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4123	qed auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4124	qed (auto simp add: assms)
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4125
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4126	lemma simplex_furthest_le:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4127	fixes s :: "'a::real_inner set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4128	assumes "finite s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4129	and "s \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4130	shows "\<exists>y\<in>s. \<forall>x\<in> convex hull s. norm (x - a) \<le> norm (y - a)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4131	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4132	have "convex hull s \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4133	using hull_subset[of s convex] and assms(2) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4134	then obtain x where x: "x \<in> convex hull s" "\<forall>y\<in>convex hull s. norm (y - a) \<le> norm (x - a)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4135	using distance_attains_sup[OF finite_imp_compact_convex_hull[OF assms(1)], of a]
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4136	unfolding dist_commute[of a]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4137	unfolding dist_norm
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4138	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4139	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4140	proof (cases "x \<in> s")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4141	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4142	then obtain y where "y \<in> convex hull s" "norm (x - a) < norm (y - a)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4143	using simplex_furthest_lt[OF assms(1), THEN bspec[where x=x]] and x(1)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4144	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4145	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4146	using x(2)[THEN bspec[where x=y]] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4147	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4148	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4149	with x show ?thesis by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4150	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4151	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4152
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4153	lemma simplex_furthest_le_exists:
44525 fbb777aec0d4 generalize lemma finite_imp_compact_convex_hull and related lemmas huffman parents: 44524 diff changeset	4154	fixes s :: "('a::real_inner) set"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4155	shows "finite s \<Longrightarrow> \<forall>x\<in>(convex hull s). \<exists>y\<in>s. norm (x - a) \<le> norm (y - a)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4156	using simplex_furthest_le[of s] by (cases "s = {}") auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4157
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4158	lemma simplex_extremal_le:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4159	fixes s :: "'a::real_inner set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4160	assumes "finite s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4161	and "s \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4162	shows "\<exists>u\<in>s. \<exists>v\<in>s. \<forall>x\<in>convex hull s. \<forall>y \<in> convex hull s. norm (x - y) \<le> norm (u - v)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4163	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4164	have "convex hull s \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4165	using hull_subset[of s convex] and assms(2) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4166	then obtain u v where obt: "u \<in> convex hull s" "v \<in> convex hull s"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4167	"\<forall>x\<in>convex hull s. \<forall>y\<in>convex hull s. norm (x - y) \<le> norm (u - v)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4168	using compact_sup_maxdistance[OF finite_imp_compact_convex_hull[OF assms(1)]]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4169	by (auto simp: dist_norm)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4170	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4171	proof (cases "u\<notin>s \<or> v\<notin>s", elim disjE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4172	assume "u \<notin> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4173	then obtain y where "y \<in> convex hull s" "norm (u - v) < norm (y - v)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4174	using simplex_furthest_lt[OF assms(1), THEN bspec[where x=u]] and obt(1)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4175	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4176	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4177	using obt(3)[THEN bspec[where x=y], THEN bspec[where x=v]] and obt(2)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4178	by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4179	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4180	assume "v \<notin> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4181	then obtain y where "y \<in> convex hull s" "norm (v - u) < norm (y - u)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4182	using simplex_furthest_lt[OF assms(1), THEN bspec[where x=v]] and obt(2)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4183	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4184	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4185	using obt(3)[THEN bspec[where x=u], THEN bspec[where x=y]] and obt(1)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4186	by (auto simp add: norm_minus_commute)
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4187	qed auto
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	4188	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4189
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4190	lemma simplex_extremal_le_exists:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4191	fixes s :: "'a::real_inner set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4192	shows "finite s \<Longrightarrow> x \<in> convex hull s \<Longrightarrow> y \<in> convex hull s \<Longrightarrow>
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4193	\<exists>u\<in>s. \<exists>v\<in>s. norm (x - y) \<le> norm (u - v)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4194	using convex_hull_empty simplex_extremal_le[of s]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4195	by(cases "s = {}") auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4196
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4197
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4198	subsection {* Closest point of a convex set is unique, with a continuous projection. *}
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4199
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4200	definition closest_point :: "'a::{real_inner,heine_borel} set \<Rightarrow> 'a \<Rightarrow> 'a"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4201	where "closest_point s a = (SOME x. x \<in> s \<and> (\<forall>y\<in>s. dist a x \<le> dist a y))"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4202
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4203	lemma closest_point_exists:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4204	assumes "closed s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4205	and "s \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4206	shows "closest_point s a \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4207	and "\<forall>y\<in>s. dist a (closest_point s a) \<le> dist a y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4208	unfolding closest_point_def
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4209	apply(rule_tac[!] someI2_ex)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4210	using distance_attains_inf[OF assms(1,2), of a]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4211	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4212	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4213
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4214	lemma closest_point_in_set: "closed s \<Longrightarrow> s \<noteq> {} \<Longrightarrow> closest_point s a \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4215	by (meson closest_point_exists)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4216
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4217	lemma closest_point_le: "closed s \<Longrightarrow> x \<in> s \<Longrightarrow> dist a (closest_point s a) \<le> dist a x"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4218	using closest_point_exists[of s] by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4219
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4220	lemma closest_point_self:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4221	assumes "x \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4222	shows "closest_point s x = x"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4223	unfolding closest_point_def
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4224	apply (rule some1_equality, rule ex1I[of _ x])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4225	using assms
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4226	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4227	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4228
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4229	lemma closest_point_refl: "closed s \<Longrightarrow> s \<noteq> {} \<Longrightarrow> closest_point s x = x \<longleftrightarrow> x \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4230	using closest_point_in_set[of s x] closest_point_self[of x s]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4231	by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4232
36337 87b6c83d7ed7 generalize constant closest_point huffman parents: 36071 diff changeset	4233	lemma closer_points_lemma:
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4234	assumes "inner y z > 0"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4235	shows "\<exists>u>0. \<forall>v>0. v \<le> u \<longrightarrow> norm(v *\<^sub>R z - y) < norm y"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4236	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4237	have z: "inner z z > 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4238	unfolding inner_gt_zero_iff using assms by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4239	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4240	using assms
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4241	apply (rule_tac x = "inner y z / inner z z" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4242	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4243	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4244	proof rule+
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4245	fix v
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4246	assume "0 < v" and "v \<le> inner y z / inner z z"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4247	then show "norm (v *\<^sub>R z - y) < norm y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4248	unfolding norm_lt using z and assms
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4249	by (simp add: field_simps inner_diff inner_commute mult_strict_left_mono[OF _ `0<v`])
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4250	qed (rule divide_pos_pos, auto)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4251	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4252
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4253	lemma closer_point_lemma:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4254	assumes "inner (y - x) (z - x) > 0"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4255	shows "\<exists>u>0. u \<le> 1 \<and> dist (x + u *\<^sub>R (z - x)) y < dist x y"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4256	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4257	obtain u where "u > 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4258	and u: "\<forall>v>0. v \<le> u \<longrightarrow> norm (v *\<^sub>R (z - x) - (y - x)) < norm (y - x)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4259	using closer_points_lemma[OF assms] by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4260	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4261	apply (rule_tac x="min u 1" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4262	using u[THEN spec[where x="min u 1"]] and `u > 0`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4263	unfolding dist_norm by (auto simp add: norm_minus_commute field_simps)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4264	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4265
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4266	lemma any_closest_point_dot:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4267	assumes "convex s" "closed s" "x \<in> s" "y \<in> s" "\<forall>z\<in>s. dist a x \<le> dist a z"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4268	shows "inner (a - x) (y - x) \<le> 0"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4269	proof (rule ccontr)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4270	assume "\<not> ?thesis"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4271	then obtain u where u: "u>0" "u\<le>1" "dist (x + u *\<^sub>R (y - x)) a < dist x a"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4272	using closer_point_lemma[of a x y] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4273	let ?z = "(1 - u) \<^sub>R x + u \<^sub>R y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4274	have "?z \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4275	using mem_convex[OF assms(1,3,4), of u] using u by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4276	then show False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4277	using assms(5)[THEN bspec[where x="?z"]] and u(3)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4278	by (auto simp add: dist_commute algebra_simps)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4279	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4280
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4281	lemma any_closest_point_unique:
36337 87b6c83d7ed7 generalize constant closest_point huffman parents: 36071 diff changeset	4282	fixes x :: "'a::real_inner"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4283	assumes "convex s" "closed s" "x \<in> s" "y \<in> s"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4284	"\<forall>z\<in>s. dist a x \<le> dist a z" "\<forall>z\<in>s. dist a y \<le> dist a z"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4285	shows "x = y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4286	using any_closest_point_dot[OF assms(1-4,5)] and any_closest_point_dot[OF assms(1-2,4,3,6)]
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4287	unfolding norm_pths(1) and norm_le_square
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4288	by (auto simp add: algebra_simps)
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4289
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4290	lemma closest_point_unique:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4291	assumes "convex s" "closed s" "x \<in> s" "\<forall>z\<in>s. dist a x \<le> dist a z"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4292	shows "x = closest_point s a"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	4293	using any_closest_point_unique[OF assms(1-3) _ assms(4), of "closest_point s a"]
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4294	using closest_point_exists[OF assms(2)] and assms(3) by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4295
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4296	lemma closest_point_dot:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4297	assumes "convex s" "closed s" "x \<in> s"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4298	shows "inner (a - closest_point s a) (x - closest_point s a) \<le> 0"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4299	apply (rule any_closest_point_dot[OF assms(1,2) _ assms(3)])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4300	using closest_point_exists[OF assms(2)] and assms(3)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4301	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4302	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4303
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4304	lemma closest_point_lt:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4305	assumes "convex s" "closed s" "x \<in> s" "x \<noteq> closest_point s a"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4306	shows "dist a (closest_point s a) < dist a x"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4307	apply (rule ccontr)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4308	apply (rule_tac notE[OF assms(4)])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4309	apply (rule closest_point_unique[OF assms(1-3), of a])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4310	using closest_point_le[OF assms(2), of _ a]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4311	apply fastforce
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4312	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4313
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4314	lemma closest_point_lipschitz:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4315	assumes "convex s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4316	and "closed s" "s \<noteq> {}"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4317	shows "dist (closest_point s x) (closest_point s y) \<le> dist x y"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4318	proof -
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4319	have "inner (x - closest_point s x) (closest_point s y - closest_point s x) \<le> 0"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4320	and "inner (y - closest_point s y) (closest_point s x - closest_point s y) \<le> 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4321	apply (rule_tac[!] any_closest_point_dot[OF assms(1-2)])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4322	using closest_point_exists[OF assms(2-3)]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4323	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4324	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4325	then show ?thesis unfolding dist_norm and norm_le
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4326	using inner_ge_zero[of "(x - closest_point s x) - (y - closest_point s y)"]
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4327	by (simp add: inner_add inner_diff inner_commute)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4328	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4329
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4330	lemma continuous_at_closest_point:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4331	assumes "convex s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4332	and "closed s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4333	and "s \<noteq> {}"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4334	shows "continuous (at x) (closest_point s)"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	4335	unfolding continuous_at_eps_delta
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4336	using le_less_trans[OF closest_point_lipschitz[OF assms]] by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4337
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4338	lemma continuous_on_closest_point:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4339	assumes "convex s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4340	and "closed s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4341	and "s \<noteq> {}"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4342	shows "continuous_on t (closest_point s)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4343	by (metis continuous_at_imp_continuous_on continuous_at_closest_point[OF assms])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4344
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4345
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	4346	subsubsection {* Various point-to-set separating/supporting hyperplane theorems. *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4347
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4348	lemma supporting_hyperplane_closed_point:
36337 87b6c83d7ed7 generalize constant closest_point huffman parents: 36071 diff changeset	4349	fixes z :: "'a::{real_inner,heine_borel}"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4350	assumes "convex s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4351	and "closed s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4352	and "s \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4353	and "z \<notin> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4354	shows "\<exists>a b. \<exists>y\<in>s. inner a z < b \<and> inner a y = b \<and> (\<forall>x\<in>s. inner a x \<ge> b)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4355	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4356	from distance_attains_inf[OF assms(2-3)]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4357	obtain y where "y \<in> s" and y: "\<forall>x\<in>s. dist z y \<le> dist z x"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4358	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4359	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4360	apply (rule_tac x="y - z" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4361	apply (rule_tac x="inner (y - z) y" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4362	apply (rule_tac x=y in bexI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4363	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4364	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4365	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4366	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4367	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4368	apply (rule ccontr)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4369	using `y \<in> s`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4370	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4371	show "inner (y - z) z < inner (y - z) y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4372	apply (subst diff_less_iff(1)[symmetric])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4373	unfolding inner_diff_right[symmetric] and inner_gt_zero_iff
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4374	using `y\<in>s` `z\<notin>s`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4375	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4376	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4377	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4378	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4379	assume "x \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4380	have : "\<forall>u. 0 \<le> u \<and> u \<le> 1 \<longrightarrow> dist z y \<le> dist z ((1 - u) \<^sub>R y + u *\<^sub>R x)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4381	using assms(1)[unfolded convex_alt] and y and `x\<in>s` and `y\<in>s` by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4382	assume "\<not> inner (y - z) y \<le> inner (y - z) x"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4383	then obtain v where "v > 0" "v \<le> 1" "dist (y + v *\<^sub>R (x - y)) z < dist y z"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4384	using closer_point_lemma[of z y x] by (auto simp add: inner_diff)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4385	then show False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4386	using *[THEN spec[where x=v]] by (auto simp add: dist_commute algebra_simps)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4387	qed auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4388	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4389
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4390	lemma separating_hyperplane_closed_point:
36337 87b6c83d7ed7 generalize constant closest_point huffman parents: 36071 diff changeset	4391	fixes z :: "'a::{real_inner,heine_borel}"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4392	assumes "convex s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4393	and "closed s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4394	and "z \<notin> s"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4395	shows "\<exists>a b. inner a z < b \<and> (\<forall>x\<in>s. inner a x > b)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4396	proof (cases "s = {}")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4397	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4398	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4399	apply (rule_tac x="-z" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4400	apply (rule_tac x=1 in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4401	using less_le_trans[OF _ inner_ge_zero[of z]]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4402	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4403	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4404	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4405	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4406	obtain y where "y \<in> s" and y: "\<forall>x\<in>s. dist z y \<le> dist z x"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4407	using distance_attains_inf[OF assms(2) False] by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4408	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4409	apply (rule_tac x="y - z" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4410	apply (rule_tac x="inner (y - z) z + (norm (y - z))\<^sup>2 / 2" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4411	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4412	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4413	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4414	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4415	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4416	assume "x \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4417	have "\<not> 0 < inner (z - y) (x - y)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4418	apply (rule notI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4419	apply (drule closer_point_lemma)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4420	proof -
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4421	assume "\<exists>u>0. u \<le> 1 \<and> dist (y + u *\<^sub>R (x - y)) z < dist y z"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4422	then obtain u where "u > 0" "u \<le> 1" "dist (y + u *\<^sub>R (x - y)) z < dist y z"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4423	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4424	then show False using y[THEN bspec[where x="y + u *\<^sub>R (x - y)"]]
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4425	using assms(1)[unfolded convex_alt, THEN bspec[where x=y]]
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4426	using `x\<in>s` `y\<in>s` by (auto simp add: dist_commute algebra_simps)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4427	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4428	moreover have "0 < (norm (y - z))\<^sup>2"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4429	using `y\<in>s` `z\<notin>s` by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4430	then have "0 < inner (y - z) (y - z)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4431	unfolding power2_norm_eq_inner by simp
53015 a1119cf551e8 standardized symbols via "isabelle update_sub_sup", excluding src/Pure and src/Tools/WWW_Find; wenzelm parents: 51524 diff changeset	4432	ultimately show "inner (y - z) z + (norm (y - z))\<^sup>2 / 2 < inner (y - z) x"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4433	unfolding power2_norm_eq_inner and not_less
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4434	by (auto simp add: field_simps inner_commute inner_diff)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4435	qed (insert `y\<in>s` `z\<notin>s`, auto)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4436	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4437
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4438	lemma separating_hyperplane_closed_0:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4439	assumes "convex (s::('a::euclidean_space) set)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4440	and "closed s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4441	and "0 \<notin> s"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4442	shows "\<exists>a b. a \<noteq> 0 \<and> 0 < b \<and> (\<forall>x\<in>s. inner a x > b)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4443	proof (cases "s = {}")
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	4444	case True
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4445	have "norm ((SOME i. i\<in>Basis)::'a) = 1" "(SOME i. i\<in>Basis) \<noteq> (0::'a)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4446	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4447	apply (subst norm_le_zero_iff[symmetric])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4448	apply (auto simp: SOME_Basis)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4449	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4450	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4451	apply (rule_tac x="SOME i. i\<in>Basis" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4452	apply (rule_tac x=1 in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4453	using True using DIM_positive[where 'a='a]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4454	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4455	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4456	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4457	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4458	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4459	using False using separating_hyperplane_closed_point[OF assms]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4460	apply (elim exE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4461	unfolding inner_zero_right
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4462	apply (rule_tac x=a in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4463	apply (rule_tac x=b in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4464	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4465	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4466	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4467
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4468
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	4469	subsubsection {* Now set-to-set for closed/compact sets *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4470
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4471	lemma separating_hyperplane_closed_compact:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4472	fixes s :: "'a::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4473	assumes "convex s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4474	and "closed s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4475	and "convex t"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4476	and "compact t"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4477	and "t \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4478	and "s \<inter> t = {}"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4479	shows "\<exists>a b. (\<forall>x\<in>s. inner a x < b) \<and> (\<forall>x\<in>t. inner a x > b)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4480	proof (cases "s = {}")
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4481	case True
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4482	obtain b where b: "b > 0" "\<forall>x\<in>t. norm x \<le> b"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4483	using compact_imp_bounded[OF assms(4)] unfolding bounded_pos by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4484	obtain z :: 'a where z: "norm z = b + 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4485	using vector_choose_size[of "b + 1"] and b(1) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4486	then have "z \<notin> t" using b(2)[THEN bspec[where x=z]] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4487	then obtain a b where ab: "inner a z < b" "\<forall>x\<in>t. b < inner a x"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4488	using separating_hyperplane_closed_point[OF assms(3) compact_imp_closed[OF assms(4)], of z]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4489	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4490	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4491	using True by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4492	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4493	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4494	then obtain y where "y \<in> s" by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4495	obtain a b where "0 < b" "\<forall>x\<in>{x - y \|x y. x \<in> s \<and> y \<in> t}. b < inner a x"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4496	using separating_hyperplane_closed_point[OF convex_differences[OF assms(1,3)], of 0]
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4497	using closed_compact_differences[OF assms(2,4)]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4498	using assms(6) by auto blast
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4499	then have ab: "\<forall>x\<in>s. \<forall>y\<in>t. b + inner a y < inner a x"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4500	apply -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4501	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4502	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4503	apply (erule_tac x="x - y" in ballE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4504	apply (auto simp add: inner_diff)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4505	done
54263 c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4506	def k \<equiv> "SUP x:t. a \<bullet> x"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4507	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4508	apply (rule_tac x="-a" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4509	apply (rule_tac x="-(k + b / 2)" in exI)
54263 c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4510	apply (intro conjI ballI)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4511	unfolding inner_minus_left and neg_less_iff_less
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4512	proof -
54263 c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4513	fix x assume "x \<in> t"
c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4514	then have "inner a x - b / 2 < k"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4515	unfolding k_def
54263 c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4516	proof (subst less_cSUP_iff)
c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4517	show "t \<noteq> {}" by fact
c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4518	show "bdd_above (op \<bullet> a ` t)"
c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4519	using ab[rule_format, of y] `y \<in> s`
c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4520	by (intro bdd_aboveI2[where M="inner a y - b"]) (auto simp: field_simps intro: less_imp_le)
c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4521	qed (auto intro!: bexI[of _ x] `0<b`)
c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4522	then show "inner a x < k + b / 2"
c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4523	by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4524	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4525	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4526	assume "x \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4527	then have "k \<le> inner a x - b"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4528	unfolding k_def
54263 c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4529	apply (rule_tac cSUP_least)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4530	using assms(5)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4531	using ab[THEN bspec[where x=x]]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4532	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4533	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4534	then show "k + b / 2 < inner a x"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4535	using `0 < b` by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4536	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4537	qed
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4538
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4539	lemma separating_hyperplane_compact_closed:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4540	fixes s :: "'a::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4541	assumes "convex s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4542	and "compact s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4543	and "s \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4544	and "convex t"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4545	and "closed t"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4546	and "s \<inter> t = {}"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4547	shows "\<exists>a b. (\<forall>x\<in>s. inner a x < b) \<and> (\<forall>x\<in>t. inner a x > b)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4548	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4549	obtain a b where "(\<forall>x\<in>t. inner a x < b) \<and> (\<forall>x\<in>s. b < inner a x)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4550	using separating_hyperplane_closed_compact[OF assms(4-5,1-2,3)] and assms(6)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4551	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4552	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4553	apply (rule_tac x="-a" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4554	apply (rule_tac x="-b" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4555	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4556	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4557	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4558
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4559
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	4560	subsubsection {* General case without assuming closure and getting non-strict separation *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4561
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4562	lemma separating_hyperplane_set_0:
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	4563	assumes "convex s" "(0::'a::euclidean_space) \<notin> s"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4564	shows "\<exists>a. a \<noteq> 0 \<and> (\<forall>x\<in>s. 0 \<le> inner a x)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4565	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4566	let ?k = "\<lambda>c. {x::'a. 0 \<le> inner c x}"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4567	have "frontier (cball 0 1) \<inter> (\<Inter> (?k ` s)) \<noteq> {}"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4568	apply (rule compact_imp_fip)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4569	apply (rule compact_frontier[OF compact_cball])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4570	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4571	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4572	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4573	apply (erule conjE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4574	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4575	fix f
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4576	assume as: "f \<subseteq> ?k ` s" "finite f"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4577	obtain c where c: "f = ?k ` c" "c \<subseteq> s" "finite c"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4578	using finite_subset_image[OF as(2,1)] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4579	then obtain a b where ab: "a \<noteq> 0" "0 < b" "\<forall>x\<in>convex hull c. b < inner a x"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4580	using separating_hyperplane_closed_0[OF convex_convex_hull, of c]
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4581	using finite_imp_compact_convex_hull[OF c(3), THEN compact_imp_closed] and assms(2)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4582	using subset_hull[of convex, OF assms(1), symmetric, of c]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4583	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4584	then have "\<exists>x. norm x = 1 \<and> (\<forall>y\<in>c. 0 \<le> inner y x)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4585	apply (rule_tac x = "inverse(norm a) *\<^sub>R a" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4586	using hull_subset[of c convex]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4587	unfolding subset_eq and inner_scaleR
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4588	apply -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4589	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4590	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4591	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4592	apply (rule mult_nonneg_nonneg)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4593	apply (auto simp add: inner_commute del: ballE elim!: ballE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4594	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4595	then show "frontier (cball 0 1) \<inter> \<Inter>f \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4596	unfolding c(1) frontier_cball dist_norm by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4597	qed (insert closed_halfspace_ge, auto)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4598	then obtain x where "norm x = 1" "\<forall>y\<in>s. x\<in>?k y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4599	unfolding frontier_cball dist_norm by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4600	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4601	apply (rule_tac x=x in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4602	apply (auto simp add: inner_commute)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4603	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4604	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4605
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4606	lemma separating_hyperplane_sets:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4607	fixes s t :: "'a::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4608	assumes "convex s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4609	and "convex t"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4610	and "s \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4611	and "t \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4612	and "s \<inter> t = {}"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4613	shows "\<exists>a b. a \<noteq> 0 \<and> (\<forall>x\<in>s. inner a x \<le> b) \<and> (\<forall>x\<in>t. inner a x \<ge> b)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4614	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4615	from separating_hyperplane_set_0[OF convex_differences[OF assms(2,1)]]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4616	obtain a where "a \<noteq> 0" "\<forall>x\<in>{x - y \|x y. x \<in> t \<and> y \<in> s}. 0 \<le> inner a x"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	4617	using assms(3-5) by auto
54263 c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4618	then have *: "\<And>x y. x \<in> t \<Longrightarrow> y \<in> s \<Longrightarrow> inner a y \<le> inner a x"
33270 320a1d67b9ae merged paulson parents: 33175 diff changeset	4619	by (force simp add: inner_diff)
54263 c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4620	then have bdd: "bdd_above ((op \<bullet> a)`s)"
c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4621	using `t \<noteq> {}` by (auto intro: bdd_aboveI2[OF *])
c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4622	show ?thesis
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4623	using `a\<noteq>0`
54263 c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4624	by (intro exI[of _ a] exI[of _ "SUP x:s. a \<bullet> x"])
c4159fe6fa46 move Lubs from HOL to HOL-Library (replaced by conditionally complete lattices) hoelzl parents: 54258 diff changeset	4625	(auto intro!: cSUP_upper bdd cSUP_least `a \<noteq> 0` `s \<noteq> {}` *)
33270 320a1d67b9ae merged paulson parents: 33175 diff changeset	4626	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4627
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4628
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	4629	subsection {* More convexity generalities *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4630
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4631	lemma convex_closure:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4632	fixes s :: "'a::real_normed_vector set"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4633	assumes "convex s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4634	shows "convex (closure s)"
53676 476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4635	apply (rule convexI)
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4636	apply (unfold closure_sequential, elim exE)
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4637	apply (rule_tac x="\<lambda>n. u \<^sub>R xa n + v \<^sub>R xb n" in exI)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4638	apply (rule,rule)
53676 476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4639	apply (rule convexD [OF assms])
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4640	apply (auto del: tendsto_const intro!: tendsto_intros)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4641	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4642
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4643	lemma convex_interior:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4644	fixes s :: "'a::real_normed_vector set"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4645	assumes "convex s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4646	shows "convex (interior s)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4647	unfolding convex_alt Ball_def mem_interior
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4648	apply (rule,rule,rule,rule,rule,rule)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4649	apply (elim exE conjE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4650	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4651	fix x y u
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4652	assume u: "0 \<le> u" "u \<le> (1::real)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4653	fix e d
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4654	assume ed: "ball x e \<subseteq> s" "ball y d \<subseteq> s" "0<d" "0<e"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4655	show "\<exists>e>0. ball ((1 - u) \<^sub>R x + u \<^sub>R y) e \<subseteq> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4656	apply (rule_tac x="min d e" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4657	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4658	unfolding subset_eq
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4659	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4660	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4661	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4662	fix z
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4663	assume "z \<in> ball ((1 - u) \<^sub>R x + u \<^sub>R y) (min d e)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4664	then have "(1- u) \<^sub>R (z - u \<^sub>R (y - x)) + u \<^sub>R (z + (1 - u) \<^sub>R (y - x)) \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4665	apply (rule_tac assms[unfolded convex_alt, rule_format])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4666	using ed(1,2) and u
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4667	unfolding subset_eq mem_ball Ball_def dist_norm
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4668	apply (auto simp add: algebra_simps)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4669	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4670	then show "z \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4671	using u by (auto simp add: algebra_simps)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4672	qed(insert u ed(3-4), auto)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4673	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4674
34964 4e8be3c04d37 Replaced vec1 and dest_vec1 by abbreviation. hoelzl parents: 34915 diff changeset	4675	lemma convex_hull_eq_empty[simp]: "convex hull s = {} \<longleftrightarrow> s = {}"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4676	using hull_subset[of s convex] convex_hull_empty by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4677
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4678
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4679	subsection {* Moving and scaling convex hulls. *}
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4680
53676 476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4681	lemma convex_hull_set_plus:
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4682	"convex hull (s + t) = convex hull s + convex hull t"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4683	unfolding set_plus_image
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4684	apply (subst convex_hull_linear_image [symmetric])
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4685	apply (simp add: linear_iff scaleR_right_distrib)
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4686	apply (simp add: convex_hull_Times)
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4687	done
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4688
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4689	lemma translation_eq_singleton_plus: "(\<lambda>x. a + x) ` t = {a} + t"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4690	unfolding set_plus_def by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4691
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4692	lemma convex_hull_translation:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4693	"convex hull ((\<lambda>x. a + x) ` s) = (\<lambda>x. a + x) ` (convex hull s)"
53676 476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4694	unfolding translation_eq_singleton_plus
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4695	by (simp only: convex_hull_set_plus convex_hull_singleton)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4696
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4697	lemma convex_hull_scaling:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4698	"convex hull ((\<lambda>x. c \<^sub>R x) ` s) = (\<lambda>x. c \<^sub>R x) ` (convex hull s)"
53676 476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4699	using linear_scaleR by (rule convex_hull_linear_image [symmetric])
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4700
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4701	lemma convex_hull_affinity:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4702	"convex hull ((\<lambda>x. a + c \<^sub>R x) ` s) = (\<lambda>x. a + c \<^sub>R x) ` (convex hull s)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4703	by(simp only: image_image[symmetric] convex_hull_scaling convex_hull_translation)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4704
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4705
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	4706	subsection {* Convexity of cone hulls *}
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	4707
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	4708	lemma convex_cone_hull:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4709	assumes "convex S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4710	shows "convex (cone hull S)"
53676 476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4711	proof (rule convexI)
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4712	fix x y
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4713	assume xy: "x \<in> cone hull S" "y \<in> cone hull S"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4714	then have "S \<noteq> {}"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4715	using cone_hull_empty_iff[of S] by auto
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4716	fix u v :: real
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4717	assume uv: "u \<ge> 0" "v \<ge> 0" "u + v = 1"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4718	then have : "u \<^sub>R x \<in> cone hull S" "v *\<^sub>R y \<in> cone hull S"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4719	using cone_cone_hull[of S] xy cone_def[of "cone hull S"] by auto
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4720	from * obtain cx :: real and xx where x: "u \<^sub>R x = cx \<^sub>R xx" "cx \<ge> 0" "xx \<in> S"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4721	using cone_hull_expl[of S] by auto
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4722	from * obtain cy :: real and yy where y: "v \<^sub>R y = cy \<^sub>R yy" "cy \<ge> 0" "yy \<in> S"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4723	using cone_hull_expl[of S] by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4724	{
53676 476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4725	assume "cx + cy \<le> 0"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4726	then have "u \<^sub>R x = 0" and "v \<^sub>R y = 0"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4727	using x y by auto
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4728	then have "u \<^sub>R x + v \<^sub>R y = 0"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4729	by auto
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4730	then have "u \<^sub>R x + v \<^sub>R y \<in> cone hull S"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4731	using cone_hull_contains_0[of S] `S \<noteq> {}` by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	4732	}
53676 476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4733	moreover
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4734	{
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4735	assume "cx + cy > 0"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4736	then have "(cx / (cx + cy)) \<^sub>R xx + (cy / (cx + cy)) \<^sub>R yy \<in> S"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4737	using assms mem_convex_alt[of S xx yy cx cy] x y by auto
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4738	then have "cx \<^sub>R xx + cy \<^sub>R yy \<in> cone hull S"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4739	using mem_cone_hull[of "(cx/(cx+cy)) \<^sub>R xx + (cy/(cx+cy)) \<^sub>R yy" S "cx+cy"] `cx+cy>0`
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4740	by (auto simp add: scaleR_right_distrib)
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4741	then have "u \<^sub>R x + v \<^sub>R y \<in> cone hull S"
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4742	using x y by auto
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4743	}
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4744	moreover have "cx + cy \<le> 0 \<or> cx + cy > 0" by auto
476ef9b468d2 tuned proofs about 'convex' huffman parents: 53620 diff changeset	4745	ultimately show "u \<^sub>R x + v \<^sub>R y \<in> cone hull S" by blast
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	4746	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	4747
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	4748	lemma cone_convex_hull:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4749	assumes "cone S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4750	shows "cone (convex hull S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4751	proof (cases "S = {}")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4752	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4753	then show ?thesis by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4754	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4755	case False
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	4756	then have : "0 \<in> S \<and> (\<forall>c. c > 0 \<longrightarrow> op \<^sub>R c ` S = S)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	4757	using cone_iff[of S] assms by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4758	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4759	fix c :: real
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4760	assume "c > 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4761	then have "op \<^sub>R c ` (convex hull S) = convex hull (op \<^sub>R c ` S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4762	using convex_hull_scaling[of _ S] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4763	also have "\<dots> = convex hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4764	using * `c > 0` by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4765	finally have "op *\<^sub>R c ` (convex hull S) = convex hull S"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4766	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	4767	}
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4768	then have "0 \<in> convex hull S" "\<And>c. c > 0 \<Longrightarrow> (op *\<^sub>R c ` (convex hull S)) = (convex hull S)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4769	using * hull_subset[of S convex] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4770	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4771	using `S \<noteq> {}` cone_iff[of "convex hull S"] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	4772	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	4773
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	4774	subsection {* Convex set as intersection of halfspaces *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4775
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4776	lemma convex_halfspace_intersection:
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	4777	fixes s :: "('a::euclidean_space) set"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4778	assumes "closed s" "convex s"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4779	shows "s = \<Inter> {h. s \<subseteq> h \<and> (\<exists>a b. h = {x. inner a x \<le> b})}"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4780	apply (rule set_eqI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4781	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4782	unfolding Inter_iff Ball_def mem_Collect_eq
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4783	apply (rule,rule,erule conjE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4784	proof -
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	4785	fix x
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4786	assume "\<forall>xa. s \<subseteq> xa \<and> (\<exists>a b. xa = {x. inner a x \<le> b}) \<longrightarrow> x \<in> xa"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4787	then have "\<forall>a b. s \<subseteq> {x. inner a x \<le> b} \<longrightarrow> x \<in> {x. inner a x \<le> b}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4788	by blast
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4789	then show "x \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4790	apply (rule_tac ccontr)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4791	apply (drule separating_hyperplane_closed_point[OF assms(2,1)])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4792	apply (erule exE)+
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4793	apply (erule_tac x="-a" in allE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4794	apply (erule_tac x="-b" in allE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4795	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4796	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4797	qed auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4798
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4799
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	4800	subsection {* Radon's theorem (from Lars Schewe) *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4801
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4802	lemma radon_ex_lemma:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4803	assumes "finite c" "affine_dependent c"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4804	shows "\<exists>u. setsum u c = 0 \<and> (\<exists>v\<in>c. u v \<noteq> 0) \<and> setsum (\<lambda>v. u v *\<^sub>R v) c = 0"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4805	proof -
55697 abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	4806	from assms(2)[unfolded affine_dependent_explicit]
abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	4807	obtain s u where
abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	4808	"finite s" "s \<subseteq> c" "setsum u s = 0" "\<exists>v\<in>s. u v \<noteq> 0" "(\<Sum>v\<in>s. u v *\<^sub>R v) = 0"
abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	4809	by blast
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4810	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4811	apply (rule_tac x="\<lambda>v. if v\<in>s then u v else 0" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4812	unfolding if_smult scaleR_zero_left and setsum_restrict_set[OF assms(1), symmetric]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4813	apply (auto simp add: Int_absorb1)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4814	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4815	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4816
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4817	lemma radon_s_lemma:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4818	assumes "finite s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4819	and "setsum f s = (0::real)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4820	shows "setsum f {x\<in>s. 0 < f x} = - setsum f {x\<in>s. f x < 0}"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4821	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4822	have *: "\<And>x. (if f x < 0 then f x else 0) + (if 0 < f x then f x else 0) = f x"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4823	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4824	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4825	unfolding real_add_eq_0_iff[symmetric] and setsum_restrict_set''[OF assms(1)]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4826	and setsum_addf[symmetric] and *
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4827	using assms(2)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4828	apply assumption
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4829	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4830	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4831
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4832	lemma radon_v_lemma:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4833	assumes "finite s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4834	and "setsum f s = 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4835	and "\<forall>x. g x = (0::real) \<longrightarrow> f x = (0::'a::euclidean_space)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4836	shows "(setsum f {x\<in>s. 0 < g x}) = - setsum f {x\<in>s. g x < 0}"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4837	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4838	have *: "\<And>x. (if 0 < g x then f x else 0) + (if g x < 0 then f x else 0) = f x"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4839	using assms(3) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4840	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4841	unfolding eq_neg_iff_add_eq_0 and setsum_restrict_set''[OF assms(1)]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4842	and setsum_addf[symmetric] and *
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4843	using assms(2)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4844	apply assumption
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4845	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4846	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4847
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4848	lemma radon_partition:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4849	assumes "finite c" "affine_dependent c"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4850	shows "\<exists>m p. m \<inter> p = {} \<and> m \<union> p = c \<and> (convex hull m) \<inter> (convex hull p) \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4851	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4852	obtain u v where uv: "setsum u c = 0" "v\<in>c" "u v \<noteq> 0" "(\<Sum>v\<in>c. u v *\<^sub>R v) = 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4853	using radon_ex_lemma[OF assms] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4854	have fin: "finite {x \<in> c. 0 < u x}" "finite {x \<in> c. 0 > u x}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4855	using assms(1) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4856	def z \<equiv> "inverse (setsum u {x\<in>c. u x > 0}) \<^sub>R setsum (\<lambda>x. u x \<^sub>R x) {x\<in>c. u x > 0}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4857	have "setsum u {x \<in> c. 0 < u x} \<noteq> 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4858	proof (cases "u v \<ge> 0")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4859	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4860	then have "u v < 0" by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4861	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4862	proof (cases "\<exists>w\<in>{x \<in> c. 0 < u x}. u w > 0")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4863	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4864	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4865	using setsum_nonneg_eq_0_iff[of _ u, OF fin(1)] by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4866	next
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4867	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4868	then have "setsum u c \<le> setsum (\<lambda>x. if x=v then u v else 0) c"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4869	apply (rule_tac setsum_mono)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4870	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4871	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4872	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4873	unfolding setsum_delta[OF assms(1)] using uv(2) and `u v < 0` and uv(1) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4874	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4875	qed (insert setsum_nonneg_eq_0_iff[of _ u, OF fin(1)] uv(2-3), auto)
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4876
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4877	then have *: "setsum u {x\<in>c. u x > 0} > 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4878	unfolding less_le
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4879	apply (rule_tac conjI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4880	apply (rule_tac setsum_nonneg)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4881	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4882	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4883	moreover have "setsum u ({x \<in> c. 0 < u x} \<union> {x \<in> c. u x < 0}) = setsum u c"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4884	"(\<Sum>x\<in>{x \<in> c. 0 < u x} \<union> {x \<in> c. u x < 0}. u x \<^sub>R x) = (\<Sum>x\<in>c. u x \<^sub>R x)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4885	using assms(1)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4886	apply (rule_tac[!] setsum_mono_zero_left)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4887	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4888	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4889	then have "setsum u {x \<in> c. 0 < u x} = - setsum u {x \<in> c. 0 > u x}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4890	"(\<Sum>x\<in>{x \<in> c. 0 < u x}. u x \<^sub>R x) = - (\<Sum>x\<in>{x \<in> c. 0 > u x}. u x \<^sub>R x)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4891	unfolding eq_neg_iff_add_eq_0
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4892	using uv(1,4)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4893	by (auto simp add: setsum_Un_zero[OF fin, symmetric])
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	4894	moreover have "\<forall>x\<in>{v \<in> c. u v < 0}. 0 \<le> inverse (setsum u {x \<in> c. 0 < u x}) * - u x"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4895	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4896	apply (rule mult_nonneg_nonneg)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4897	using *
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4898	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4899	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4900	ultimately have "z \<in> convex hull {v \<in> c. u v \<le> 0}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4901	unfolding convex_hull_explicit mem_Collect_eq
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4902	apply (rule_tac x="{v \<in> c. u v < 0}" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4903	apply (rule_tac x="\<lambda>y. inverse (setsum u {x\<in>c. u x > 0}) * - u y" in exI)
49530 7faf67b411b4 tuned; wenzelm parents: 49529 diff changeset	4904	using assms(1) unfolding scaleR_scaleR[symmetric] scaleR_right.setsum [symmetric] and z_def
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4905	apply (auto simp add: setsum_negf setsum_right_distrib[symmetric])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4906	done
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	4907	moreover have "\<forall>x\<in>{v \<in> c. 0 < u v}. 0 \<le> inverse (setsum u {x \<in> c. 0 < u x}) * u x"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4908	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4909	apply (rule mult_nonneg_nonneg)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4910	using *
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4911	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4912	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4913	then have "z \<in> convex hull {v \<in> c. u v > 0}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4914	unfolding convex_hull_explicit mem_Collect_eq
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4915	apply (rule_tac x="{v \<in> c. 0 < u v}" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4916	apply (rule_tac x="\<lambda>y. inverse (setsum u {x\<in>c. u x > 0}) * u y" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4917	using assms(1)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4918	unfolding scaleR_scaleR[symmetric] scaleR_right.setsum [symmetric] and z_def
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4919	using *
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4920	apply (auto simp add: setsum_negf setsum_right_distrib[symmetric])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4921	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4922	ultimately show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4923	apply (rule_tac x="{v\<in>c. u v \<le> 0}" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4924	apply (rule_tac x="{v\<in>c. u v > 0}" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4925	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4926	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4927	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4928
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4929	lemma radon:
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4930	assumes "affine_dependent c"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4931	obtains m p where "m \<subseteq> c" "p \<subseteq> c" "m \<inter> p = {}" "(convex hull m) \<inter> (convex hull p) \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4932	proof -
55697 abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	4933	from assms[unfolded affine_dependent_explicit]
abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	4934	obtain s u where
abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	4935	"finite s" "s \<subseteq> c" "setsum u s = 0" "\<exists>v\<in>s. u v \<noteq> 0" "(\<Sum>v\<in>s. u v *\<^sub>R v) = 0"
abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	4936	by blast
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4937	then have *: "finite s" "affine_dependent s" and s: "s \<subseteq> c"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4938	unfolding affine_dependent_explicit by auto
55697 abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	4939	from radon_partition[OF *]
abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	4940	obtain m p where "m \<inter> p = {}" "m \<union> p = s" "convex hull m \<inter> convex hull p \<noteq> {}"
abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	4941	by blast
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4942	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4943	apply (rule_tac that[of p m])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4944	using s
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4945	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4946	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4947	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4948
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4949
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	4950	subsection {* Helly's theorem *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	4951
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4952	lemma helly_induct:
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4953	fixes f :: "'a::euclidean_space set set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4954	assumes "card f = n"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4955	and "n \<ge> DIM('a) + 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4956	and "\<forall>s\<in>f. convex s" "\<forall>t\<subseteq>f. card t = DIM('a) + 1 \<longrightarrow> \<Inter> t \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4957	shows "\<Inter>f \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4958	using assms
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4959	proof (induct n arbitrary: f)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4960	case 0
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4961	then show ?case by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4962	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4963	case (Suc n)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4964	have "finite f"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4965	using `card f = Suc n` by (auto intro: card_ge_0_finite)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4966	show "\<Inter>f \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4967	apply (cases "n = DIM('a)")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4968	apply (rule Suc(5)[rule_format])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4969	unfolding `card f = Suc n`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4970	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4971	assume ng: "n \<noteq> DIM('a)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4972	then have "\<exists>X. \<forall>s\<in>f. X s \<in> \<Inter>(f - {s})"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4973	apply (rule_tac bchoice)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4974	unfolding ex_in_conv
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4975	apply (rule, rule Suc(1)[rule_format])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4976	unfolding card_Diff_singleton_if[OF `finite f`] `card f = Suc n`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4977	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4978	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4979	apply (rule Suc(4)[rule_format])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4980	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4981	apply (rule Suc(5)[rule_format])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4982	using Suc(3) `finite f`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4983	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4984	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4985	then obtain X where X: "\<forall>s\<in>f. X s \<in> \<Inter>(f - {s})" by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4986	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4987	proof (cases "inj_on X f")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4988	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4989	then obtain s t where st: "s\<noteq>t" "s\<in>f" "t\<in>f" "X s = X t"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4990	unfolding inj_on_def by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4991	then have *: "\<Inter>f = \<Inter>(f - {s}) \<inter> \<Inter>(f - {t})" by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4992	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4993	unfolding *
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4994	unfolding ex_in_conv[symmetric]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4995	apply (rule_tac x="X s" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4996	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4997	apply (rule X[rule_format])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4998	using X st
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	4999	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5000	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5001	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5002	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5003	then obtain m p where mp: "m \<inter> p = {}" "m \<union> p = X ` f" "convex hull m \<inter> convex hull p \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5004	using radon_partition[of "X ` f"] and affine_dependent_biggerset[of "X ` f"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5005	unfolding card_image[OF True] and `card f = Suc n`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5006	using Suc(3) `finite f` and ng
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5007	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5008	have "m \<subseteq> X ` f" "p \<subseteq> X ` f"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5009	using mp(2) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5010	then obtain g h where gh:"m = X ` g" "p = X ` h" "g \<subseteq> f" "h \<subseteq> f"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5011	unfolding subset_image_iff by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5012	then have "f \<union> (g \<union> h) = f" by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5013	then have f: "f = g \<union> h"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5014	using inj_on_Un_image_eq_iff[of X f "g \<union> h"] and True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5015	unfolding mp(2)[unfolded image_Un[symmetric] gh]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5016	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5017	have *: "g \<inter> h = {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5018	using mp(1)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5019	unfolding gh
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5020	using inj_on_image_Int[OF True gh(3,4)]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5021	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5022	have "convex hull (X ` h) \<subseteq> \<Inter>g" "convex hull (X ` g) \<subseteq> \<Inter>h"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5023	apply (rule_tac [!] hull_minimal)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5024	using Suc gh(3-4)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5025	unfolding subset_eq
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5026	apply (rule_tac [2] convex_Inter, rule_tac [4] convex_Inter)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5027	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5028	prefer 3
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5029	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5030	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5031	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5032	assume "x \<in> X ` g"
55697 abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	5033	then obtain y where "y \<in> g" "x = X y"
abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	5034	unfolding image_iff ..
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5035	then show "x \<in> \<Inter>h"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5036	using X[THEN bspec[where x=y]] using * f by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5037	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5038	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5039	assume "x \<in> X ` h"
55697 abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	5040	then obtain y where "y \<in> h" "x = X y"
abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	5041	unfolding image_iff ..
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5042	then show "x \<in> \<Inter>g"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5043	using X[THEN bspec[where x=y]] using * f by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5044	qed auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5045	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5046	unfolding f using mp(3)[unfolded gh] by blast
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5047	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5048	qed auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5049	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5050
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5051	lemma helly:
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5052	fixes f :: "'a::euclidean_space set set"
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	5053	assumes "card f \<ge> DIM('a) + 1" "\<forall>s\<in>f. convex s"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5054	and "\<forall>t\<subseteq>f. card t = DIM('a) + 1 \<longrightarrow> \<Inter> t \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5055	shows "\<Inter>f \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5056	apply (rule helly_induct)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5057	using assms
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5058	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5059	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5060
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5061
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	5062	subsection {* Homeomorphism of all convex compact sets with nonempty interior *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5063
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5064	lemma compact_frontier_line_lemma:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5065	fixes s :: "'a::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5066	assumes "compact s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5067	and "0 \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5068	and "x \<noteq> 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5069	obtains u where "0 \<le> u" and "(u \<^sub>R x) \<in> frontier s" "\<forall>v>u. (v \<^sub>R x) \<notin> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5070	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5071	obtain b where b: "b > 0" "\<forall>x\<in>s. norm x \<le> b"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5072	using compact_imp_bounded[OF assms(1), unfolded bounded_pos] by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5073	let ?A = "{y. \<exists>u. 0 \<le> u \<and> u \<le> b / norm(x) \<and> (y = u *\<^sub>R x)}"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5074	have A: "?A = (\<lambda>u. u *\<^sub>R x) ` {0 .. b / norm x}"
36431 340755027840 move definitions and theorems for type real^1 to separate theory file huffman parents: 36365 diff changeset	5075	by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5076	have *: "\<And>x A B. x\<in>A \<Longrightarrow> x\<in>B \<Longrightarrow> A\<inter>B \<noteq> {}" by blast
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5077	have "compact ?A"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5078	unfolding A
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5079	apply (rule compact_continuous_image)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5080	apply (rule continuous_at_imp_continuous_on)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5081	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5082	apply (intro continuous_intros)
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5083	apply (rule compact_Icc)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5084	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5085	moreover have "{y. \<exists>u\<ge>0. u \<le> b / norm x \<and> y = u *\<^sub>R x} \<inter> s \<noteq> {}"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5086	apply(rule *[OF _ assms(2)])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5087	unfolding mem_Collect_eq
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5088	using `b > 0` assms(3)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5089	apply (auto intro!: divide_nonneg_pos)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5090	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5091	ultimately obtain u y where obt: "u\<ge>0" "u \<le> b / norm x" "y = u *\<^sub>R x"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5092	"y \<in> ?A" "y \<in> s" "\<forall>z\<in>?A \<inter> s. dist 0 z \<le> dist 0 y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5093	using distance_attains_sup[OF compact_inter[OF _ assms(1), of ?A], of 0]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5094	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5095
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5096	have "norm x > 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5097	using assms(3)[unfolded zero_less_norm_iff[symmetric]] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5098	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5099	fix v
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5100	assume as: "v > u" "v *\<^sub>R x \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5101	then have "v \<le> b / norm x"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5102	using b(2)[rule_format, OF as(2)]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5103	using `u\<ge>0`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5104	unfolding pos_le_divide_eq[OF `norm x > 0`]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5105	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5106	then have "norm (v *\<^sub>R x) \<le> norm y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5107	apply (rule_tac obt(6)[rule_format, unfolded dist_0_norm])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5108	apply (rule IntI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5109	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5110	apply (rule as(2))
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5111	unfolding mem_Collect_eq
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5112	apply (rule_tac x=v in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5113	using as(1) `u\<ge>0`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5114	apply (auto simp add: field_simps)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5115	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5116	then have False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5117	unfolding obt(3) using `u\<ge>0` `norm x > 0` `v > u`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5118	by (auto simp add:field_simps)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5119	} note u_max = this
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5120
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5121	have "u *\<^sub>R x \<in> frontier s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5122	unfolding frontier_straddle
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5123	apply (rule,rule,rule)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5124	apply (rule_tac x="u *\<^sub>R x" in bexI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5125	unfolding obt(3)[symmetric]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5126	prefer 3
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5127	apply (rule_tac x="(u + (e / 2) / norm x) *\<^sub>R x" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5128	apply (rule, rule)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5129	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5130	fix e
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5131	assume "e > 0" and as: "(u + e / 2 / norm x) *\<^sub>R x \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5132	then have "u + e / 2 / norm x > u"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5133	using `norm x > 0` by (auto simp del:zero_less_norm_iff intro!: divide_pos_pos)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5134	then show False using u_max[OF _ as] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5135	qed (insert `y\<in>s`, auto simp add: dist_norm scaleR_left_distrib obt(3))
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5136	then show ?thesis by(metis that[of u] u_max obt(1))
36071 c8ae8e56d42e tuned many proofs a bit nipkow parents: 35577 diff changeset	5137	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5138
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5139	lemma starlike_compact_projective:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5140	assumes "compact s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5141	and "cball (0::'a::euclidean_space) 1 \<subseteq> s "
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5142	and "\<forall>x\<in>s. \<forall>u. 0 \<le> u \<and> u < 1 \<longrightarrow> u *\<^sub>R x \<in> s - frontier s"
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	5143	shows "s homeomorphic (cball (0::'a::euclidean_space) 1)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5144	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5145	have fs: "frontier s \<subseteq> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5146	apply (rule frontier_subset_closed)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5147	using compact_imp_closed[OF assms(1)]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5148	apply simp
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5149	done
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	5150	def pi \<equiv> "\<lambda>x::'a. inverse (norm x) *\<^sub>R x"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5151	have "0 \<notin> frontier s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5152	unfolding frontier_straddle
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5153	apply (rule notI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5154	apply (erule_tac x=1 in allE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5155	using assms(2)[unfolded subset_eq Ball_def mem_cball]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5156	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5157	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5158	have injpi: "\<And>x y. pi x = pi y \<and> norm x = norm y \<longleftrightarrow> x = y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5159	unfolding pi_def by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5160
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5161	have contpi: "continuous_on (UNIV - {0}) pi"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5162	apply (rule continuous_at_imp_continuous_on)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5163	apply rule unfolding pi_def
44647 e4de7750cdeb modernize lemmas about 'continuous' and 'continuous_on'; huffman parents: 44629 diff changeset	5164	apply (intro continuous_intros)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5165	apply simp
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5166	done
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	5167	def sphere \<equiv> "{x::'a. norm x = 1}"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5168	have pi: "\<And>x. x \<noteq> 0 \<Longrightarrow> pi x \<in> sphere" "\<And>x u. u>0 \<Longrightarrow> pi (u *\<^sub>R x) = pi x"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5169	unfolding pi_def sphere_def by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5170
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5171	have "0 \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5172	using assms(2) and centre_in_cball[of 0 1] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5173	have front_smul: "\<forall>x\<in>frontier s. \<forall>u\<ge>0. u *\<^sub>R x \<in> s \<longleftrightarrow> u \<le> 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5174	proof (rule,rule,rule)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5175	fix x and u :: real
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5176	assume x: "x \<in> frontier s" and "0 \<le> u"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5177	then have "x \<noteq> 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5178	using `0 \<notin> frontier s` by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5179	obtain v where v: "0 \<le> v" "v \<^sub>R x \<in> frontier s" "\<forall>w>v. w \<^sub>R x \<notin> s"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5180	using compact_frontier_line_lemma[OF assms(1) `0\<in>s` `x\<noteq>0`] by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5181	have "v = 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5182	apply (rule ccontr)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5183	unfolding neq_iff
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5184	apply (erule disjE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5185	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5186	assume "v < 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5187	then show False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5188	using v(3)[THEN spec[where x=1]] using x and fs by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5189	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5190	assume "v > 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5191	then show False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5192	using assms(3)[THEN bspec[where x="v *\<^sub>R x"], THEN spec[where x="inverse v"]]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5193	using v and x and fs
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5194	unfolding inverse_less_1_iff by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5195	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5196	show "u *\<^sub>R x \<in> s \<longleftrightarrow> u \<le> 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5197	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5198	using v(3)[unfolded `v=1`, THEN spec[where x=u]]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5199	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5200	assume "u \<le> 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5201	then show "u *\<^sub>R x \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5202	apply (cases "u = 1")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5203	using assms(3)[THEN bspec[where x=x], THEN spec[where x=u]]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5204	using `0\<le>u` and x and fs
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5205	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5206	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5207	qed auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5208	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5209
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5210	have "\<exists>surf. homeomorphism (frontier s) sphere pi surf"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5211	apply (rule homeomorphism_compact)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5212	apply (rule compact_frontier[OF assms(1)])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5213	apply (rule continuous_on_subset[OF contpi])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5214	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5215	apply (rule set_eqI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5216	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5217	unfolding inj_on_def
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5218	prefer 3
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5219	apply(rule,rule,rule)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5220	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5221	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5222	assume "x \<in> pi ` frontier s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5223	then obtain y where "y \<in> frontier s" "x = pi y" by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5224	then show "x \<in> sphere"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5225	using pi(1)[of y] and `0 \<notin> frontier s` by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5226	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5227	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5228	assume "x \<in> sphere"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5229	then have "norm x = 1" "x \<noteq> 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5230	unfolding sphere_def by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5231	then obtain u where "0 \<le> u" "u \<^sub>R x \<in> frontier s" "\<forall>v>u. v \<^sub>R x \<notin> s"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5232	using compact_frontier_line_lemma[OF assms(1) `0\<in>s`, of x] by auto
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5233	then show "x \<in> pi ` frontier s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5234	unfolding image_iff le_less pi_def
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5235	apply (rule_tac x="u *\<^sub>R x" in bexI)
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5236	using `norm x = 1` `0 \<notin> frontier s`
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5237	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5238	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5239	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5240	fix x y
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5241	assume as: "x \<in> frontier s" "y \<in> frontier s" "pi x = pi y"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5242	then have xys: "x \<in> s" "y \<in> s"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5243	using fs by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5244	from as(1,2) have nor: "norm x \<noteq> 0" "norm y \<noteq> 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5245	using `0\<notin>frontier s` by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5246	from nor have x: "x = norm x \<^sub>R ((inverse (norm y)) \<^sub>R y)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5247	unfolding as(3)[unfolded pi_def, symmetric] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5248	from nor have y: "y = norm y \<^sub>R ((inverse (norm x)) \<^sub>R x)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5249	unfolding as(3)[unfolded pi_def] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5250	have "0 \<le> norm y * inverse (norm x)" and "0 \<le> norm x * inverse (norm y)"
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5251	unfolding divide_inverse[symmetric]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5252	apply (rule_tac[!] divide_nonneg_pos)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5253	using nor
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5254	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5255	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5256	then have "norm x = norm y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5257	apply -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5258	apply (rule ccontr)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5259	unfolding neq_iff
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5260	using x y and front_smul[THEN bspec, OF as(1), THEN spec[where x="norm y * (inverse (norm x))"]]
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5261	using front_smul[THEN bspec, OF as(2), THEN spec[where x="norm x * (inverse (norm y))"]]
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5262	using xys nor
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5263	apply (auto simp add:field_simps divide_le_eq_1 divide_inverse[symmetric])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5264	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5265	then show "x = y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5266	apply (subst injpi[symmetric])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5267	using as(3)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5268	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5269	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5270	qed (insert `0 \<notin> frontier s`, auto)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5271	then obtain surf where
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5272	surf: "\<forall>x\<in>frontier s. surf (pi x) = x" "pi ` frontier s = sphere" "continuous_on (frontier s) pi"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5273	"\<forall>y\<in>sphere. pi (surf y) = y" "surf ` sphere = frontier s" "continuous_on sphere surf"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5274	unfolding homeomorphism_def by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5275
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5276	have cont_surfpi: "continuous_on (UNIV - {0}) (surf \<circ> pi)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5277	apply (rule continuous_on_compose)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5278	apply (rule contpi)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5279	apply (rule continuous_on_subset[of sphere])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5280	apply (rule surf(6))
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5281	using pi(1)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5282	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5283	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5284
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5285	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5286	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5287	assume as: "x \<in> cball (0::'a) 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5288	have "norm x *\<^sub>R surf (pi x) \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5289	proof (cases "x=0 \<or> norm x = 1")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5290	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5291	then have "pi x \<in> sphere" "norm x < 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5292	using pi(1)[of x] as by(auto simp add: dist_norm)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5293	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5294	apply (rule_tac assms(3)[rule_format, THEN DiffD1])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5295	apply (rule_tac fs[unfolded subset_eq, rule_format])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5296	unfolding surf(5)[symmetric]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5297	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5298	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5299	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5300	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5301	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5302	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5303	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5304	unfolding pi_def
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5305	apply (rule fs[unfolded subset_eq, rule_format])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5306	unfolding surf(5)[unfolded sphere_def, symmetric]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5307	using `0\<in>s`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5308	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5309	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5310	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5311	} note hom = this
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5312
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5313	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5314	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5315	assume "x \<in> s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5316	then have "x \<in> (\<lambda>x. norm x *\<^sub>R surf (pi x)) ` cball 0 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5317	proof (cases "x = 0")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5318	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5319	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5320	unfolding image_iff True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5321	apply (rule_tac x=0 in bexI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5322	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5323	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5324	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5325	let ?a = "inverse (norm (surf (pi x)))"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5326	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5327	then have invn: "inverse (norm x) \<noteq> 0" by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5328	from False have pix: "pi x\<in>sphere" using pi(1) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5329	then have "pi (surf (pi x)) = pi x"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5330	apply (rule_tac surf(4)[rule_format])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5331	apply assumption
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5332	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5333	then have *: "norm x \<^sub>R (?a *\<^sub>R surf (pi x)) = x"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5334	apply (rule_tac scaleR_left_imp_eq[OF invn])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5335	unfolding pi_def
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5336	using invn
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5337	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5338	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5339	then have : "?a norm x > 0" and "?a > 0" "?a \<noteq> 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5340	using surf(5) `0\<notin>frontier s`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5341	apply -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5342	apply (rule mult_pos_pos)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5343	using False[unfolded zero_less_norm_iff[symmetric]]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5344	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5345	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5346	have "norm (surf (pi x)) \<noteq> 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5347	using ** False by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5348	then have "norm x = norm ((?a * norm x) *\<^sub>R surf (pi x))"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5349	unfolding norm_scaleR abs_mult abs_norm_cancel abs_of_pos[OF `?a > 0`] by auto
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	5350	moreover have "pi x = pi ((inverse (norm (surf (pi x))) * norm x) *\<^sub>R surf (pi x))"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5351	unfolding pi(2)[OF *] surf(4)[rule_format, OF pix] ..
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5352	moreover have "surf (pi x) \<in> frontier s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5353	using surf(5) pix by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5354	then have "dist 0 (inverse (norm (surf (pi x))) *\<^sub>R x) \<le> 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5355	unfolding dist_norm
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5356	using ** and *
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5357	using front_smul[THEN bspec[where x="surf (pi x)"], THEN spec[where x="norm x * ?a"]]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5358	using False `x\<in>s`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5359	by (auto simp add: field_simps)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5360	ultimately show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5361	unfolding image_iff
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5362	apply (rule_tac x="inverse (norm (surf(pi x))) *\<^sub>R x" in bexI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5363	apply (subst injpi[symmetric])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5364	unfolding abs_mult abs_norm_cancel abs_of_pos[OF `?a > 0`]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5365	unfolding pi(2)[OF `?a > 0`]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5366	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5367	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5368	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5369	} note hom2 = this
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5370
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5371	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5372	apply (subst homeomorphic_sym)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5373	apply (rule homeomorphic_compact[where f="\<lambda>x. norm x *\<^sub>R surf (pi x)"])
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5374	apply (rule compact_cball)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5375	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5376	apply (rule set_eqI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5377	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5378	apply (erule imageE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5379	apply (drule hom)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5380	prefer 4
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5381	apply (rule continuous_at_imp_continuous_on)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5382	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5383	apply (rule_tac [3] hom2)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5384	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5385	fix x :: 'a
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5386	assume as: "x \<in> cball 0 1"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5387	then show "continuous (at x) (\<lambda>x. norm x *\<^sub>R surf (pi x))"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5388	proof (cases "x = 0")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5389	case False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5390	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5391	apply (intro continuous_intros)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5392	using cont_surfpi
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5393	unfolding continuous_on_eq_continuous_at[OF open_delete[OF open_UNIV]] o_def
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5394	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5395	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5396	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5397	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5398	obtain B where B: "\<forall>x\<in>s. norm x \<le> B"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5399	using compact_imp_bounded[OF assms(1)] unfolding bounded_iff by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5400	then have "B > 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5401	using assms(2)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5402	unfolding subset_eq
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5403	apply (erule_tac x="SOME i. i\<in>Basis" in ballE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5404	defer
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5405	apply (erule_tac x="SOME i. i\<in>Basis" in ballE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5406	unfolding Ball_def mem_cball dist_norm
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5407	using DIM_positive[where 'a='a]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5408	apply (auto simp: SOME_Basis)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5409	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5410	show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5411	unfolding True continuous_at Lim_at
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5412	apply(rule,rule)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5413	apply(rule_tac x="e / B" in exI)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5414	apply rule
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5415	apply (rule divide_pos_pos)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5416	prefer 3
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5417	apply(rule,rule,erule conjE)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5418	unfolding norm_zero scaleR_zero_left dist_norm diff_0_right norm_scaleR abs_norm_cancel
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5419	proof -
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5420	fix e and x :: 'a
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5421	assume as: "norm x < e / B" "0 < norm x" "e > 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5422	then have "surf (pi x) \<in> frontier s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5423	using pi(1)[of x] unfolding surf(5)[symmetric] by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5424	then have "norm (surf (pi x)) \<le> B"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5425	using B fs by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5426	then have "norm x * norm (surf (pi x)) \<le> norm x * B"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5427	using as(2) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5428	also have "\<dots> < e / B * B"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5429	apply (rule mult_strict_right_mono)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5430	using as(1) `B>0`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5431	apply auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5432	done
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5433	also have "\<dots> = e" using `B > 0` by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5434	finally show "norm x * norm (surf (pi x)) < e" .
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5435	qed (insert `B>0`, auto)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5436	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5437	next
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5438	{
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5439	fix x
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5440	assume as: "surf (pi x) = 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5441	have "x = 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5442	proof (rule ccontr)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5443	assume "x \<noteq> 0"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5444	then have "pi x \<in> sphere"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5445	using pi(1) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5446	then have "surf (pi x) \<in> frontier s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5447	using surf(5) by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5448	then show False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5449	using `0\<notin>frontier s` unfolding as by simp
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5450	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5451	} note surf_0 = this
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5452	show "inj_on (\<lambda>x. norm x *\<^sub>R surf (pi x)) (cball 0 1)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5453	unfolding inj_on_def
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5454	proof (rule,rule,rule)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5455	fix x y
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5456	assume as: "x \<in> cball 0 1" "y \<in> cball 0 1" "norm x \<^sub>R surf (pi x) = norm y \<^sub>R surf (pi y)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5457	then show "x = y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5458	proof (cases "x=0 \<or> y=0")
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5459	case True
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5460	then show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5461	using as by (auto elim: surf_0)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5462	next
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5463	case False
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5464	then have "pi (surf (pi x)) = pi (surf (pi y))"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5465	using as(3)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5466	using pi(2)[of "norm x" "surf (pi x)"] pi(2)[of "norm y" "surf (pi y)"]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5467	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5468	moreover have "pi x \<in> sphere" "pi y \<in> sphere"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5469	using pi(1) False by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5470	ultimately have *: "pi x = pi y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5471	using surf(4)[THEN bspec[where x="pi x"]] surf(4)[THEN bspec[where x="pi y"]]
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5472	by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5473	moreover have "norm x = norm y"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5474	using as(3)[unfolded *] using False
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5475	by (auto dest:surf_0)
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5476	ultimately show ?thesis
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5477	using injpi by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5478	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5479	qed
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5480	qed auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5481	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5482
44519 ea85d78a994e simplify definition of 'interior'; huffman parents: 44467 diff changeset	5483	lemma homeomorphic_convex_compact_lemma:
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5484	fixes s :: "'a::euclidean_space set"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5485	assumes "convex s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5486	and "compact s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5487	and "cball 0 1 \<subseteq> s"
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	5488	shows "s homeomorphic (cball (0::'a) 1)"
44519 ea85d78a994e simplify definition of 'interior'; huffman parents: 44467 diff changeset	5489	proof (rule starlike_compact_projective[OF assms(2-3)], clarify)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5490	fix x u
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5491	assume "x \<in> s" and "0 \<le> u" and "u < (1::real)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5492	have "open (ball (u *\<^sub>R x) (1 - u))"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5493	by (rule open_ball)
44519 ea85d78a994e simplify definition of 'interior'; huffman parents: 44467 diff changeset	5494	moreover have "u \<^sub>R x \<in> ball (u \<^sub>R x) (1 - u)"
ea85d78a994e simplify definition of 'interior'; huffman parents: 44467 diff changeset	5495	unfolding centre_in_ball using `u < 1` by simp
ea85d78a994e simplify definition of 'interior'; huffman parents: 44467 diff changeset	5496	moreover have "ball (u *\<^sub>R x) (1 - u) \<subseteq> s"
ea85d78a994e simplify definition of 'interior'; huffman parents: 44467 diff changeset	5497	proof
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5498	fix y
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5499	assume "y \<in> ball (u *\<^sub>R x) (1 - u)"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5500	then have "dist (u *\<^sub>R x) y < 1 - u"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5501	unfolding mem_ball .
44519 ea85d78a994e simplify definition of 'interior'; huffman parents: 44467 diff changeset	5502	with `u < 1` have "inverse (1 - u) \<^sub>R (y - u \<^sub>R x) \<in> cball 0 1"
ea85d78a994e simplify definition of 'interior'; huffman parents: 44467 diff changeset	5503	by (simp add: dist_norm inverse_eq_divide norm_minus_commute)
ea85d78a994e simplify definition of 'interior'; huffman parents: 44467 diff changeset	5504	with assms(3) have "inverse (1 - u) \<^sub>R (y - u \<^sub>R x) \<in> s" ..
ea85d78a994e simplify definition of 'interior'; huffman parents: 44467 diff changeset	5505	with assms(1) have "(1 - u) \<^sub>R ((y - u \<^sub>R x) /\<^sub>R (1 - u)) + u *\<^sub>R x \<in> s"
ea85d78a994e simplify definition of 'interior'; huffman parents: 44467 diff changeset	5506	using `x \<in> s` `0 \<le> u` `u < 1` [THEN less_imp_le] by (rule mem_convex)
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5507	then show "y \<in> s" using `u < 1`
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5508	by simp
44519 ea85d78a994e simplify definition of 'interior'; huffman parents: 44467 diff changeset	5509	qed
ea85d78a994e simplify definition of 'interior'; huffman parents: 44467 diff changeset	5510	ultimately have "u *\<^sub>R x \<in> interior s" ..
53347 547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5511	then show "u *\<^sub>R x \<in> s - frontier s"
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5512	using frontier_def and interior_subset by auto
547610c26257 tuned proofs; wenzelm parents: 53339 diff changeset	5513	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5514
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5515	lemma homeomorphic_convex_compact_cball:
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5516	fixes e :: real
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5517	and s :: "'a::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5518	assumes "convex s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5519	and "compact s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5520	and "interior s \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5521	and "e > 0"
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	5522	shows "s homeomorphic (cball (b::'a) e)"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5523	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5524	obtain a where "a \<in> interior s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5525	using assms(3) by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5526	then obtain d where "d > 0" and d: "cball a d \<subseteq> s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5527	unfolding mem_interior_cball by auto
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	5528	let ?d = "inverse d" and ?n = "0::'a"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5529	have "cball ?n 1 \<subseteq> (\<lambda>x. inverse d *\<^sub>R (x - a)) ` s"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5530	apply rule
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5531	apply (rule_tac x="d *\<^sub>R x + a" in image_eqI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5532	defer
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5533	apply (rule d[unfolded subset_eq, rule_format])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5534	using `d > 0`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5535	unfolding mem_cball dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5536	apply (auto simp add: mult_right_le_one_le)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5537	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5538	then have "(\<lambda>x. inverse d *\<^sub>R (x - a)) ` s homeomorphic cball ?n 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5539	using homeomorphic_convex_compact_lemma[of "(\<lambda>x. ?d \<^sub>R -a + ?d \<^sub>R x) ` s",
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5540	OF convex_affinity compact_affinity]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5541	using assms(1,2)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5542	by (auto simp add: uminus_add_conv_diff scaleR_right_diff_distrib)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5543	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5544	apply (rule_tac homeomorphic_trans[OF _ homeomorphic_balls(2)[of 1 _ ?n]])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5545	apply (rule homeomorphic_trans[OF homeomorphic_affinity[of "?d" s "?d *\<^sub>R -a"]])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5546	using `d>0` `e>0`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5547	apply (auto simp add: uminus_add_conv_diff scaleR_right_diff_distrib)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5548	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5549	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5550
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5551	lemma homeomorphic_convex_compact:
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5552	fixes s :: "'a::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5553	and t :: "'a set"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5554	assumes "convex s" "compact s" "interior s \<noteq> {}"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5555	and "convex t" "compact t" "interior t \<noteq> {}"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5556	shows "s homeomorphic t"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5557	using assms
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5558	by (meson zero_less_one homeomorphic_trans homeomorphic_convex_compact_cball homeomorphic_sym)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5559
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5560
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	5561	subsection {* Epigraphs of convex functions *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5562
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5563	definition "epigraph s (f :: _ \<Rightarrow> real) = {xy. fst xy \<in> s \<and> f (fst xy) \<le> snd xy}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5564
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5565	lemma mem_epigraph: "(x, y) \<in> epigraph s f \<longleftrightarrow> x \<in> s \<and> f x \<le> y"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5566	unfolding epigraph_def by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5567
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5568	lemma convex_epigraph: "convex (epigraph s f) \<longleftrightarrow> convex_on s f \<and> convex s"
36338 7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	5569	unfolding convex_def convex_on_def
7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	5570	unfolding Ball_def split_paired_All epigraph_def
7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	5571	unfolding mem_Collect_eq fst_conv snd_conv fst_add snd_add fst_scaleR snd_scaleR Ball_def[symmetric]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5572	apply safe
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5573	defer
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5574	apply (erule_tac x=x in allE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5575	apply (erule_tac x="f x" in allE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5576	apply safe
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5577	apply (erule_tac x=xa in allE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5578	apply (erule_tac x="f xa" in allE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5579	prefer 3
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5580	apply (rule_tac y="u * f a + v * f aa" in order_trans)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5581	defer
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5582	apply (auto intro!:mult_left_mono add_mono)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5583	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5584
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5585	lemma convex_epigraphI: "convex_on s f \<Longrightarrow> convex s \<Longrightarrow> convex (epigraph s f)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5586	unfolding convex_epigraph by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5587
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5588	lemma convex_epigraph_convex: "convex s \<Longrightarrow> convex_on s f \<longleftrightarrow> convex(epigraph s f)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5589	by (simp add: convex_epigraph)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5590
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5591
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	5592	subsubsection {* Use this to derive general bound property of convex function *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5593
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5594	lemma convex_on:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5595	assumes "convex s"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5596	shows "convex_on s f \<longleftrightarrow>
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5597	(\<forall>k u x. (\<forall>i\<in>{1..k::nat}. 0 \<le> u i \<and> x i \<in> s) \<and> setsum u {1..k} = 1 \<longrightarrow>
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5598	f (setsum (\<lambda>i. u i \<^sub>R x i) {1..k} ) \<le> setsum (\<lambda>i. u i f(x i)) {1..k})"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5599	unfolding convex_epigraph_convex[OF assms] convex epigraph_def Ball_def mem_Collect_eq
36338 7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	5600	unfolding fst_setsum snd_setsum fst_scaleR snd_scaleR
7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	5601	apply safe
7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	5602	apply (drule_tac x=k in spec)
7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	5603	apply (drule_tac x=u in spec)
7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	5604	apply (drule_tac x="\<lambda>i. (x i, f (x i))" in spec)
7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	5605	apply simp
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5606	using assms[unfolded convex]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5607	apply simp
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5608	apply (rule_tac y="\<Sum>i = 1..k. u i * f (fst (x i))" in order_trans)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5609	defer
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5610	apply (rule setsum_mono)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5611	apply (erule_tac x=i in allE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5612	unfolding real_scaleR_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5613	apply (rule mult_left_mono)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5614	using assms[unfolded convex]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5615	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5616	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5617
36338 7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	5618
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	5619	subsection {* Convexity of general and special intervals *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5620
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5621	lemma is_interval_convex:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5622	fixes s :: "'a::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5623	assumes "is_interval s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5624	shows "convex s"
37732 6432bf0d7191 generalize type of is_interval to class euclidean_space huffman parents: 37673 diff changeset	5625	proof (rule convexI)
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5626	fix x y and u v :: real
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5627	assume as: "x \<in> s" "y \<in> s" "0 \<le> u" "0 \<le> v" "u + v = 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5628	then have : "u = 1 - v" "1 - v \<ge> 0" and *: "v = 1 - u" "1 - u \<ge> 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5629	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5630	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5631	fix a b
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5632	assume "\<not> b \<le> u * a + v * b"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5633	then have "u * a < (1 - v) * b"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5634	unfolding not_le using as(4) by (auto simp add: field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5635	then have "a < b"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5636	unfolding * using as(4) *(2)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5637	apply (rule_tac mult_left_less_imp_less[of "1 - v"])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5638	apply (auto simp add: field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5639	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5640	then have "a \<le> u * a + v * b"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5641	unfolding * using as(4)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5642	by (auto simp add: field_simps intro!:mult_right_mono)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5643	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5644	moreover
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5645	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5646	fix a b
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5647	assume "\<not> u * a + v * b \<le> a"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5648	then have "v * b > (1 - u) * a"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5649	unfolding not_le using as(4) by (auto simp add: field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5650	then have "a < b"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5651	unfolding * using as(4)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5652	apply (rule_tac mult_left_less_imp_less)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5653	apply (auto simp add: field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5654	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5655	then have "u * a + v * b \<le> b"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5656	unfolding **
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5657	using **(2) as(3)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5658	by (auto simp add: field_simps intro!:mult_right_mono)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5659	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5660	ultimately show "u \<^sub>R x + v \<^sub>R y \<in> s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5661	apply -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5662	apply (rule assms[unfolded is_interval_def, rule_format, OF as(1,2)])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5663	using as(3-) DIM_positive[where 'a='a]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5664	apply (auto simp: inner_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5665	done
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	5666	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5667
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5668	lemma is_interval_connected:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5669	fixes s :: "'a::euclidean_space set"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5670	shows "is_interval s \<Longrightarrow> connected s"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5671	using is_interval_convex convex_connected by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5672
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5673	lemma convex_box: "convex (cbox a b)" "convex (box a (b::'a::euclidean_space))"
0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5674	apply (rule_tac[!] is_interval_convex)+
56189 c4daa97ac57a removed dependencies on theory Ordered_Euclidean_Space immler parents: 56188 diff changeset	5675	using is_interval_box is_interval_cbox
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5676	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5677	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5678
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5679	subsection {* On @{text "real"}, @{text "is_interval"}, @{text "convex"} and @{text "connected"} are all equivalent. *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5680
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5681	lemma is_interval_1:
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5682	"is_interval (s::real set) \<longleftrightarrow> (\<forall>a\<in>s. \<forall>b\<in>s. \<forall> x. a \<le> x \<and> x \<le> b \<longrightarrow> x \<in> s)"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5683	unfolding is_interval_def by auto
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5684
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5685	lemma is_interval_connected_1:
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5686	fixes s :: "real set"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5687	shows "is_interval s \<longleftrightarrow> connected s"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5688	apply rule
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5689	apply (rule is_interval_connected, assumption)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5690	unfolding is_interval_1
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5691	apply rule
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5692	apply rule
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5693	apply rule
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5694	apply rule
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5695	apply (erule conjE)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5696	apply (rule ccontr)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5697	proof -
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5698	fix a b x
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5699	assume as: "connected s" "a \<in> s" "b \<in> s" "a \<le> x" "x \<le> b" "x \<notin> s"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5700	then have *: "a < x" "x < b"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5701	unfolding not_le [symmetric] by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5702	let ?halfl = "{..<x} "
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5703	let ?halfr = "{x<..}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5704	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5705	fix y
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5706	assume "y \<in> s"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5707	with `x \<notin> s` have "x \<noteq> y" by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5708	then have "y \<in> ?halfr \<union> ?halfl" by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5709	}
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5710	moreover have "a \<in> ?halfl" "b \<in> ?halfr" using * by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5711	then have "?halfl \<inter> s \<noteq> {}" "?halfr \<inter> s \<noteq> {}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5712	using as(2-3) by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5713	ultimately show False
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5714	apply (rule_tac notE[OF as(1)[unfolded connected_def]])
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5715	apply (rule_tac x = ?halfl in exI)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5716	apply (rule_tac x = ?halfr in exI)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5717	apply rule
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5718	apply (rule open_lessThan)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5719	apply rule
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5720	apply (rule open_greaterThan)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5721	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5722	done
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5723	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5724
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5725	lemma is_interval_convex_1:
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5726	fixes s :: "real set"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5727	shows "is_interval s \<longleftrightarrow> convex s"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5728	by (metis is_interval_convex convex_connected is_interval_connected_1)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5729
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5730	lemma convex_connected_1:
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5731	fixes s :: "real set"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5732	shows "connected s \<longleftrightarrow> convex s"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	5733	by (metis is_interval_convex convex_connected is_interval_connected_1)
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5734
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5735
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	5736	subsection {* Another intermediate value theorem formulation *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5737
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5738	lemma ivt_increasing_component_on_1:
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5739	fixes f :: "real \<Rightarrow> 'a::euclidean_space"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5740	assumes "a \<le> b"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5741	and "continuous_on (cbox a b) f"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5742	and "(f a)\<bullet>k \<le> y" "y \<le> (f b)\<bullet>k"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5743	shows "\<exists>x\<in>cbox a b. (f x)\<bullet>k = y"
0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5744	proof -
0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5745	have "f a \<in> f ` cbox a b" "f b \<in> f ` cbox a b"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5746	apply (rule_tac[!] imageI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5747	using assms(1)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5748	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5749	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5750	then show ?thesis
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5751	using connected_ivt_component[of "f ` cbox a b" "f a" "f b" k y]
0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5752	using connected_continuous_image[OF assms(2) convex_connected[OF convex_box(1)]]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5753	using assms
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5754	by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5755	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5756
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5757	lemma ivt_increasing_component_1:
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5758	fixes f :: "real \<Rightarrow> 'a::euclidean_space"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5759	shows "a \<le> b \<Longrightarrow> \<forall>x\<in>cbox a b. continuous (at x) f \<Longrightarrow>
0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5760	f a\<bullet>k \<le> y \<Longrightarrow> y \<le> f b\<bullet>k \<Longrightarrow> \<exists>x\<in>cbox a b. (f x)\<bullet>k = y"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5761	by (rule ivt_increasing_component_on_1) (auto simp add: continuous_at_imp_continuous_on)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5762
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5763	lemma ivt_decreasing_component_on_1:
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5764	fixes f :: "real \<Rightarrow> 'a::euclidean_space"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5765	assumes "a \<le> b"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5766	and "continuous_on (cbox a b) f"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5767	and "(f b)\<bullet>k \<le> y"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5768	and "y \<le> (f a)\<bullet>k"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5769	shows "\<exists>x\<in>cbox a b. (f x)\<bullet>k = y"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5770	apply (subst neg_equal_iff_equal[symmetric])
44531 1d477a2b1572 replace some continuous_on lemmas with more general versions huffman parents: 44525 diff changeset	5771	using ivt_increasing_component_on_1[of a b "\<lambda>x. - f x" k "- y"]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5772	using assms using continuous_on_minus
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5773	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5774	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5775
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5776	lemma ivt_decreasing_component_1:
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5777	fixes f :: "real \<Rightarrow> 'a::euclidean_space"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5778	shows "a \<le> b \<Longrightarrow> \<forall>x\<in>cbox a b. continuous (at x) f \<Longrightarrow>
0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5779	f b\<bullet>k \<le> y \<Longrightarrow> y \<le> f a\<bullet>k \<Longrightarrow> \<exists>x\<in>cbox a b. (f x)\<bullet>k = y"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5780	by (rule ivt_decreasing_component_on_1) (auto simp: continuous_at_imp_continuous_on)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5781
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5782
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	5783	subsection {* A bound within a convex hull, and so an interval *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5784
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5785	lemma convex_on_convex_hull_bound:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5786	assumes "convex_on (convex hull s) f"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5787	and "\<forall>x\<in>s. f x \<le> b"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5788	shows "\<forall>x\<in> convex hull s. f x \<le> b"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5789	proof
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5790	fix x
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5791	assume "x \<in> convex hull s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5792	then obtain k u v where
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5793	obt: "\<forall>i\<in>{1..k::nat}. 0 \<le> u i \<and> v i \<in> s" "setsum u {1..k} = 1" "(\<Sum>i = 1..k. u i *\<^sub>R v i) = x"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5794	unfolding convex_hull_indexed mem_Collect_eq by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5795	have "(\<Sum>i = 1..k. u i * f (v i)) \<le> b"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5796	using setsum_mono[of "{1..k}" "\<lambda>i. u i * f (v i)" "\<lambda>i. u i * b"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5797	unfolding setsum_left_distrib[symmetric] obt(2) mult_1
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5798	apply (drule_tac meta_mp)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5799	apply (rule mult_left_mono)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5800	using assms(2) obt(1)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5801	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5802	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5803	then show "f x \<le> b"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5804	using assms(1)[unfolded convex_on[OF convex_convex_hull], rule_format, of k u v]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5805	unfolding obt(2-3)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5806	using obt(1) and hull_subset[unfolded subset_eq, rule_format, of _ s]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5807	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5808	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5809
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5810	lemma inner_setsum_Basis[simp]: "i \<in> Basis \<Longrightarrow> (\<Sum>Basis) \<bullet> i = 1"
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5811	by (simp add: inner_setsum_left setsum_cases inner_Basis)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5812
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5813	lemma convex_set_plus:
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5814	assumes "convex s" and "convex t" shows "convex (s + t)"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5815	proof -
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5816	have "convex {x + y \|x y. x \<in> s \<and> y \<in> t}"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5817	using assms by (rule convex_sums)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5818	moreover have "{x + y \|x y. x \<in> s \<and> y \<in> t} = s + t"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5819	unfolding set_plus_def by auto
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5820	finally show "convex (s + t)" .
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5821	qed
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5822
55929 91f245c23bc5 remove lemmas in favor of more general ones: convex(_hull)_set_{plus,setsum} huffman parents: 55928 diff changeset	5823	lemma convex_set_setsum:
91f245c23bc5 remove lemmas in favor of more general ones: convex(_hull)_set_{plus,setsum} huffman parents: 55928 diff changeset	5824	assumes "\<And>i. i \<in> A \<Longrightarrow> convex (B i)"
91f245c23bc5 remove lemmas in favor of more general ones: convex(_hull)_set_{plus,setsum} huffman parents: 55928 diff changeset	5825	shows "convex (\<Sum>i\<in>A. B i)"
91f245c23bc5 remove lemmas in favor of more general ones: convex(_hull)_set_{plus,setsum} huffman parents: 55928 diff changeset	5826	proof (cases "finite A")
91f245c23bc5 remove lemmas in favor of more general ones: convex(_hull)_set_{plus,setsum} huffman parents: 55928 diff changeset	5827	case True then show ?thesis using assms
91f245c23bc5 remove lemmas in favor of more general ones: convex(_hull)_set_{plus,setsum} huffman parents: 55928 diff changeset	5828	by induct (auto simp: convex_set_plus)
91f245c23bc5 remove lemmas in favor of more general ones: convex(_hull)_set_{plus,setsum} huffman parents: 55928 diff changeset	5829	qed auto
91f245c23bc5 remove lemmas in favor of more general ones: convex(_hull)_set_{plus,setsum} huffman parents: 55928 diff changeset	5830
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5831	lemma finite_set_setsum:
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5832	assumes "finite A" and "\<forall>i\<in>A. finite (B i)" shows "finite (\<Sum>i\<in>A. B i)"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5833	using assms by (induct set: finite, simp, simp add: finite_set_plus)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5834
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5835	lemma set_setsum_eq:
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5836	"finite A \<Longrightarrow> (\<Sum>i\<in>A. B i) = {\<Sum>i\<in>A. f i \|f. \<forall>i\<in>A. f i \<in> B i}"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5837	apply (induct set: finite)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5838	apply simp
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5839	apply simp
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5840	apply (safe elim!: set_plus_elim)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5841	apply (rule_tac x="fun_upd f x a" in exI)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5842	apply simp
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5843	apply (rule_tac f="\<lambda>x. a + x" in arg_cong)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5844	apply (rule setsum_cong [OF refl])
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5845	apply clarsimp
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5846	apply (fast intro: set_plus_intro)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5847	done
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5848
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5849	lemma box_eq_set_setsum_Basis:
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5850	shows "{x. \<forall>i\<in>Basis. x\<bullet>i \<in> B i} = (\<Sum>i\<in>Basis. image (\<lambda>x. x *\<^sub>R i) (B i))"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5851	apply (subst set_setsum_eq [OF finite_Basis])
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5852	apply safe
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5853	apply (fast intro: euclidean_representation [symmetric])
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5854	apply (subst inner_setsum_left)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5855	apply (subgoal_tac "(\<Sum>x\<in>Basis. f x \<bullet> i) = f i \<bullet> i")
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5856	apply (drule (1) bspec)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5857	apply clarsimp
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5858	apply (frule setsum_diff1' [OF finite_Basis])
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5859	apply (erule trans)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5860	apply simp
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5861	apply (rule setsum_0')
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5862	apply clarsimp
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5863	apply (frule_tac x=i in bspec, assumption)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5864	apply (drule_tac x=x in bspec, assumption)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5865	apply clarsimp
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5866	apply (cut_tac u=x and v=i in inner_Basis, assumption+)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5867	apply (rule ccontr)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5868	apply simp
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5869	done
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5870
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5871	lemma convex_hull_set_setsum:
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5872	"convex hull (\<Sum>i\<in>A. B i) = (\<Sum>i\<in>A. convex hull (B i))"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5873	proof (cases "finite A")
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5874	assume "finite A" then show ?thesis
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5875	by (induct set: finite, simp, simp add: convex_hull_set_plus)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5876	qed simp
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5877
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5878	lemma bounded_linear_imp_linear: "bounded_linear f \<Longrightarrow> linear f" (* TODO: move elsewhere *)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5879	proof -
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5880	assume "bounded_linear f"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5881	then interpret f: bounded_linear f .
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5882	show "linear f"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5883	by (simp add: f.add f.scaleR linear_iff)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5884	qed
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5885
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5886	lemma convex_hull_eq_real_cbox:
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5887	fixes x y :: real assumes "x \<le> y"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5888	shows "convex hull {x, y} = cbox x y"
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5889	proof (rule hull_unique)
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5890	show "{x, y} \<subseteq> cbox x y" using `x \<le> y` by auto
0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5891	show "convex (cbox x y)"
0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5892	by (rule convex_box)
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5893	next
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5894	fix s assume "{x, y} \<subseteq> s" and "convex s"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5895	then show "cbox x y \<subseteq> s"
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5896	unfolding is_interval_convex_1 [symmetric] is_interval_def Basis_real_def
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5897	by - (clarify, simp (no_asm_use), fast)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5898	qed
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	5899
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5900	lemma unit_interval_convex_hull:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5901	defines "One \<equiv> \<Sum>Basis"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5902	shows "cbox (0::'a::euclidean_space) One = convex hull {x. \<forall>i\<in>Basis. (x\<bullet>i = 0) \<or> (x\<bullet>i = 1)}"
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	5903	(is "?int = convex hull ?points")
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	5904	proof -
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	5905	have One[simp]: "\<And>i. i \<in> Basis \<Longrightarrow> One \<bullet> i = 1"
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	5906	by (simp add: One_def inner_setsum_left setsum_cases inner_Basis)
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5907	have "?int = {x. \<forall>i\<in>Basis. x \<bullet> i \<in> cbox 0 1}"
0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5908	by (auto simp: cbox_def)
0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5909	also have "\<dots> = (\<Sum>i\<in>Basis. (\<lambda>x. x *\<^sub>R i) ` cbox 0 1)"
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5910	by (simp only: box_eq_set_setsum_Basis)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5911	also have "\<dots> = (\<Sum>i\<in>Basis. (\<lambda>x. x *\<^sub>R i) ` (convex hull {0, 1}))"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5912	by (simp only: convex_hull_eq_real_cbox zero_le_one)
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5913	also have "\<dots> = (\<Sum>i\<in>Basis. convex hull ((\<lambda>x. x *\<^sub>R i) ` {0, 1}))"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5914	by (simp only: convex_hull_linear_image linear_scaleR_left)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5915	also have "\<dots> = convex hull (\<Sum>i\<in>Basis. (\<lambda>x. x *\<^sub>R i) ` {0, 1})"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5916	by (simp only: convex_hull_set_setsum)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5917	also have "\<dots> = convex hull {x. \<forall>i\<in>Basis. x\<bullet>i \<in> {0, 1}}"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5918	by (simp only: box_eq_set_setsum_Basis)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5919	also have "convex hull {x. \<forall>i\<in>Basis. x\<bullet>i \<in> {0, 1}} = convex hull ?points"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5920	by simp
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	5921	finally show ?thesis .
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	5922	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5923
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	5924	text {* And this is a finite set of vertices. *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5925
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	5926	lemma unit_cube_convex_hull:
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5927	obtains s :: "'a::euclidean_space set"
0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5928	where "finite s" and "cbox 0 (\<Sum>Basis) = convex hull s"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5929	apply (rule that[of "{x::'a. \<forall>i\<in>Basis. x\<bullet>i=0 \<or> x\<bullet>i=1}"])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5930	apply (rule finite_subset[of _ "(\<lambda>s. (\<Sum>i\<in>Basis. (if i\<in>s then 1 else 0) *\<^sub>R i)::'a) ` Pow Basis"])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5931	prefer 3
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5932	apply (rule unit_interval_convex_hull)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5933	apply rule
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5934	unfolding mem_Collect_eq
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5935	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5936	fix x :: 'a
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5937	assume as: "\<forall>i\<in>Basis. x \<bullet> i = 0 \<or> x \<bullet> i = 1"
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	5938	show "x \<in> (\<lambda>s. \<Sum>i\<in>Basis. (if i\<in>s then 1 else 0) *\<^sub>R i) ` Pow Basis"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5939	apply (rule image_eqI[where x="{i. i\<in>Basis \<and> x\<bullet>i = 1}"])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5940	using as
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5941	apply (subst euclidean_eq_iff)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5942	apply (auto simp: inner_setsum_left_Basis)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5943	done
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	5944	qed auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5945
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	5946	text {* Hence any cube (could do any nonempty interval). *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5947
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5948	lemma cube_convex_hull:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5949	assumes "d > 0"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5950	obtains s :: "'a::euclidean_space set" where
0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5951	"finite s" and "cbox (x - (\<Sum>i\<in>Basis. d\<^sub>Ri)) (x + (\<Sum>i\<in>Basis. d\<^sub>Ri)) = convex hull s"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5952	proof -
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	5953	let ?d = "(\<Sum>i\<in>Basis. d*\<^sub>Ri)::'a"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5954	have : "cbox (x - ?d) (x + ?d) = (\<lambda>y. x - ?d + (2 d) *\<^sub>R y) ` cbox 0 (\<Sum>Basis)"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5955	apply (rule set_eqI, rule)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5956	unfolding image_iff
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5957	defer
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5958	apply (erule bexE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5959	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5960	fix y
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5961	assume as: "y\<in>cbox (x - ?d) (x + ?d)"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5962	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5963	fix i :: 'a
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5964	assume i: "i \<in> Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5965	have "x \<bullet> i \<le> d + y \<bullet> i" "y \<bullet> i \<le> d + x \<bullet> i"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5966	using as[unfolded mem_box, THEN bspec[where x=i]] i
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	5967	by (auto simp: inner_simps)
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5968	then have "1 \<ge> inverse d * (x \<bullet> i - y \<bullet> i)" "1 \<ge> inverse d * (y \<bullet> i - x \<bullet> i)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5969	apply (rule_tac[!] mult_left_le_imp_le[OF _ assms])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5970	unfolding mult_assoc[symmetric]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5971	using assms
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5972	by (auto simp add: field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5973	then have "inverse d * (x \<bullet> i * 2) \<le> 2 + inverse d * (y \<bullet> i * 2)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5974	"inverse d * (y \<bullet> i * 2) \<le> 2 + inverse d * (x \<bullet> i * 2)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5975	by (auto simp add:field_simps) }
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5976	then have "inverse (2 * d) *\<^sub>R (y - (x - ?d)) \<in> cbox 0 (\<Sum>Basis)"
0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5977	unfolding mem_box using assms
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5978	by (auto simp add: field_simps inner_simps)
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5979	then show "\<exists>z\<in>cbox 0 (\<Sum>Basis). y = x - ?d + (2 * d) *\<^sub>R z"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5980	apply -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5981	apply (rule_tac x="inverse (2 * d) *\<^sub>R (y - (x - ?d))" in bexI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5982	using assms
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5983	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5984	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	5985	next
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5986	fix y z
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5987	assume as: "z\<in>cbox 0 (\<Sum>Basis)" "y = x - ?d + (2d) \<^sub>R z"
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	5988	have "\<And>i. i\<in>Basis \<Longrightarrow> 0 \<le> d * (z \<bullet> i) \<and> d * (z \<bullet> i) \<le> d"
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5989	using assms as(1)[unfolded mem_box]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5990	apply (erule_tac x=i in ballE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5991	apply rule
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5992	apply (rule mult_nonneg_nonneg)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5993	prefer 3
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5994	apply (rule mult_right_le_one_le)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5995	using assms
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5996	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	5997	done
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5998	then show "y \<in> cbox (x - ?d) (x + ?d)"
0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	5999	unfolding as(2) mem_box
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6000	apply -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6001	apply rule
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	6002	using as(1)[unfolded mem_box]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6003	apply (erule_tac x=i in ballE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6004	using assms
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6005	apply (auto simp: inner_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6006	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6007	qed
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	6008	obtain s where "finite s" "cbox 0 (\<Sum>Basis::'a) = convex hull s"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6009	using unit_cube_convex_hull by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6010	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6011	apply (rule_tac that[of "(\<lambda>y. x - ?d + (2 * d) *\<^sub>R y)` s"])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6012	unfolding * and convex_hull_affinity
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6013	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6014	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6015	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6016
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6017
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	6018	subsection {* Bounded convex function on open set is continuous *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6019
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6020	lemma convex_on_bounded_continuous:
36338 7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	6021	fixes s :: "('a::real_normed_vector) set"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6022	assumes "open s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6023	and "convex_on s f"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6024	and "\<forall>x\<in>s. abs(f x) \<le> b"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6025	shows "continuous_on s f"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6026	apply (rule continuous_at_imp_continuous_on)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6027	unfolding continuous_at_real_range
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6028	proof (rule,rule,rule)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6029	fix x and e :: real
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6030	assume "x \<in> s" "e > 0"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6031	def B \<equiv> "abs b + 1"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6032	have B: "0 < B" "\<And>x. x\<in>s \<Longrightarrow> abs (f x) \<le> B"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6033	unfolding B_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6034	defer
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6035	apply (drule assms(3)[rule_format])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6036	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6037	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6038	obtain k where "k > 0" and k: "cball x k \<subseteq> s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6039	using assms(1)[unfolded open_contains_cball, THEN bspec[where x=x]]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6040	using `x\<in>s` by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6041	show "\<exists>d>0. \<forall>x'. norm (x' - x) < d \<longrightarrow> \<bar>f x' - f x\<bar> < e"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6042	apply (rule_tac x="min (k / 2) (e / (2 * B) * k)" in exI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6043	apply rule
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6044	defer
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6045	proof (rule, rule)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6046	fix y
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6047	assume as: "norm (y - x) < min (k / 2) (e / (2 * B) * k)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6048	show "\<bar>f y - f x\<bar> < e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6049	proof (cases "y = x")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6050	case False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6051	def t \<equiv> "k / norm (y - x)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6052	have "2 < t" "0<t"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6053	unfolding t_def using as False and `k>0`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6054	by (auto simp add:field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6055	have "y \<in> s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6056	apply (rule k[unfolded subset_eq,rule_format])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6057	unfolding mem_cball dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6058	apply (rule order_trans[of _ "2 * norm (x - y)"])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6059	using as
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6060	by (auto simp add: field_simps norm_minus_commute)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6061	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6062	def w \<equiv> "x + t *\<^sub>R (y - x)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6063	have "w \<in> s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6064	unfolding w_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6065	apply (rule k[unfolded subset_eq,rule_format])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6066	unfolding mem_cball dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6067	unfolding t_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6068	using `k>0`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6069	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6070	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6071	have "(1 / t) \<^sub>R x + - x + ((t - 1) / t) \<^sub>R x = (1 / t - 1 + (t - 1) / t) *\<^sub>R x"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6072	by (auto simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6073	also have "\<dots> = 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6074	using `t > 0` by (auto simp add:field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6075	finally have w: "(1 / t) \<^sub>R w + ((t - 1) / t) \<^sub>R x = y"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6076	unfolding w_def using False and `t > 0`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6077	by (auto simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6078	have "2 * B < e * t"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6079	unfolding t_def using `0 < e` `0 < k` `B > 0` and as and False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6080	by (auto simp add:field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6081	then have "(f w - f x) / t < e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6082	using B(2)[OF `w\<in>s`] and B(2)[OF `x\<in>s`]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6083	using `t > 0` by (auto simp add:field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6084	then have th1: "f y - f x < e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6085	apply -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6086	apply (rule le_less_trans)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6087	defer
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6088	apply assumption
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6089	using assms(2)[unfolded convex_on_def,rule_format,of w x "1/t" "(t - 1)/t", unfolded w]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6090	using `0 < t` `2 < t` and `x \<in> s` `w \<in> s`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6091	by (auto simp add:field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6092	}
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	6093	moreover
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6094	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6095	def w \<equiv> "x - t *\<^sub>R (y - x)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6096	have "w \<in> s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6097	unfolding w_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6098	apply (rule k[unfolded subset_eq,rule_format])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6099	unfolding mem_cball dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6100	unfolding t_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6101	using `k > 0`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6102	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6103	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6104	have "(1 / (1 + t)) \<^sub>R x + (t / (1 + t)) \<^sub>R x = (1 / (1 + t) + t / (1 + t)) *\<^sub>R x"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6105	by (auto simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6106	also have "\<dots> = x"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6107	using `t > 0` by (auto simp add:field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6108	finally have w: "(1 / (1+t)) \<^sub>R w + (t / (1 + t)) \<^sub>R y = x"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6109	unfolding w_def using False and `t > 0`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6110	by (auto simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6111	have "2 * B < e * t"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6112	unfolding t_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6113	using `0 < e` `0 < k` `B > 0` and as and False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6114	by (auto simp add:field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6115	then have *: "(f w - f y) / t < e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6116	using B(2)[OF `w\<in>s`] and B(2)[OF `y\<in>s`]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6117	using `t > 0`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6118	by (auto simp add:field_simps)
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	6119	have "f x \<le> 1 / (1 + t) * f w + (t / (1 + t)) * f y"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6120	using assms(2)[unfolded convex_on_def,rule_format,of w y "1/(1+t)" "t / (1+t)",unfolded w]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6121	using `0 < t` `2 < t` and `y \<in> s` `w \<in> s`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6122	by (auto simp add:field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6123	also have "\<dots> = (f w + t * f y) / (1 + t)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6124	using `t > 0` unfolding divide_inverse by (auto simp add: field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6125	also have "\<dots> < e + f y"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6126	using `t > 0` * `e > 0` by (auto simp add: field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6127	finally have "f x - f y < e" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6128	}
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	6129	ultimately show ?thesis by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6130	qed (insert `0<e`, auto)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6131	qed (insert `0<e` `0<k` `0<B`, auto simp add:field_simps intro!:mult_pos_pos)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6132	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6133
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6134
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	6135	subsection {* Upper bound on a ball implies upper and lower bounds *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6136
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6137	lemma convex_bounds_lemma:
36338 7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	6138	fixes x :: "'a::real_normed_vector"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6139	assumes "convex_on (cball x e) f"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6140	and "\<forall>y \<in> cball x e. f y \<le> b"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6141	shows "\<forall>y \<in> cball x e. abs (f y) \<le> b + 2 * abs (f x)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6142	apply rule
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6143	proof (cases "0 \<le> e")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6144	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6145	fix y
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6146	assume y: "y \<in> cball x e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6147	def z \<equiv> "2 *\<^sub>R x - y"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6148	have : "x - (2 \<^sub>R x - y) = y - x"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6149	by (simp add: scaleR_2)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6150	have z: "z \<in> cball x e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6151	using y unfolding z_def mem_cball dist_norm * by (auto simp add: norm_minus_commute)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6152	have "(1 / 2) \<^sub>R y + (1 / 2) \<^sub>R z = x"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6153	unfolding z_def by (auto simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6154	then show "\<bar>f y\<bar> \<le> b + 2 * \<bar>f x\<bar>"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6155	using assms(1)[unfolded convex_on_def,rule_format, OF y z, of "1/2" "1/2"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6156	using assms(2)[rule_format,OF y] assms(2)[rule_format,OF z]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6157	by (auto simp add:field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6158	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6159	case False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6160	fix y
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6161	assume "y \<in> cball x e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6162	then have "dist x y < 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6163	using False unfolding mem_cball not_le by (auto simp del: dist_not_less_zero)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6164	then show "\<bar>f y\<bar> \<le> b + 2 * \<bar>f x\<bar>"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6165	using zero_le_dist[of x y] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6166	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6167
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6168
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	6169	subsubsection {* Hence a convex function on an open set is continuous *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6170
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6171	lemma real_of_nat_ge_one_iff: "1 \<le> real (n::nat) \<longleftrightarrow> 1 \<le> n"
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6172	by auto
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6173
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6174	lemma convex_on_continuous:
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6175	assumes "open (s::('a::euclidean_space) set)" "convex_on s f"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6176	shows "continuous_on s f"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6177	unfolding continuous_on_eq_continuous_at[OF assms(1)]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6178	proof
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	6179	note dimge1 = DIM_positive[where 'a='a]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6180	fix x
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6181	assume "x \<in> s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6182	then obtain e where e: "cball x e \<subseteq> s" "e > 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6183	using assms(1) unfolding open_contains_cball by auto
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	6184	def d \<equiv> "e / real DIM('a)"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6185	have "0 < d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6186	unfolding d_def using `e > 0` dimge1
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6187	apply (rule_tac divide_pos_pos)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6188	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6189	done
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6190	let ?d = "(\<Sum>i\<in>Basis. d *\<^sub>R i)::'a"
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6191	obtain c
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6192	where c: "finite c"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6193	and c1: "convex hull c \<subseteq> cball x e"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6194	and c2: "cball x d \<subseteq> convex hull c"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6195	proof
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6196	def c \<equiv> "\<Sum>i\<in>Basis. (\<lambda>a. a *\<^sub>R i) ` {x\<bullet>i - d, x\<bullet>i + d}"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6197	show "finite c"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6198	unfolding c_def by (simp add: finite_set_setsum)
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	6199	have 1: "convex hull c = {a. \<forall>i\<in>Basis. a \<bullet> i \<in> cbox (x \<bullet> i - d) (x \<bullet> i + d)}"
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6200	unfolding box_eq_set_setsum_Basis
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6201	unfolding c_def convex_hull_set_setsum
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6202	apply (subst convex_hull_linear_image [symmetric])
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6203	apply (simp add: linear_iff scaleR_add_left)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6204	apply (rule setsum_cong [OF refl])
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6205	apply (rule image_cong [OF _ refl])
56188 0268784f60da use cbox to relax class constraints immler parents: 56154 diff changeset	6206	apply (rule convex_hull_eq_real_cbox)
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6207	apply (cut_tac `0 < d`, simp)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6208	done
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6209	then have 2: "convex hull c = {a. \<forall>i\<in>Basis. a \<bullet> i \<in> cball (x \<bullet> i) d}"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6210	by (simp add: dist_norm abs_le_iff algebra_simps)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6211	show "cball x d \<subseteq> convex hull c"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6212	unfolding 2
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6213	apply clarsimp
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6214	apply (simp only: dist_norm)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6215	apply (subst inner_diff_left [symmetric])
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6216	apply simp
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6217	apply (erule (1) order_trans [OF Basis_le_norm])
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6218	done
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6219	have e': "e = (\<Sum>(i::'a)\<in>Basis. d)"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6220	by (simp add: d_def real_of_nat_def DIM_positive)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6221	show "convex hull c \<subseteq> cball x e"
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6222	unfolding 2
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6223	apply clarsimp
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6224	apply (subst euclidean_dist_l2)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6225	apply (rule order_trans [OF setL2_le_setsum])
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6226	apply (rule zero_le_dist)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6227	unfolding e'
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6228	apply (rule setsum_mono)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6229	apply simp
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6230	done
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6231	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6232	def k \<equiv> "Max (f ` c)"
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6233	have "convex_on (convex hull c) f"
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6234	apply(rule convex_on_subset[OF assms(2)])
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6235	apply(rule subset_trans[OF _ e(1)])
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6236	apply(rule c1)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6237	done
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6238	then have k: "\<forall>y\<in>convex hull c. f y \<le> k"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6239	apply (rule_tac convex_on_convex_hull_bound)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6240	apply assumption
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6241	unfolding k_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6242	apply (rule, rule Max_ge)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6243	using c(1)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6244	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6245	done
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6246	have "d \<le> e"
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6247	unfolding d_def
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6248	apply (rule mult_imp_div_pos_le)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6249	using `e > 0`
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6250	unfolding mult_le_cancel_left1
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6251	apply (auto simp: real_of_nat_ge_one_iff Suc_le_eq DIM_positive)
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6252	done
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6253	then have dsube: "cball x d \<subseteq> cball x e"
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6254	by (rule subset_cball)
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6255	have conv: "convex_on (cball x d) f"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6256	apply (rule convex_on_subset)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6257	apply (rule convex_on_subset[OF assms(2)])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6258	apply (rule e(1))
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6259	apply (rule dsube)
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6260	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6261	then have "\<forall>y\<in>cball x d. abs (f y) \<le> k + 2 * abs (f x)"
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6262	apply (rule convex_bounds_lemma)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6263	apply (rule ballI)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6264	apply (rule k [rule_format])
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6265	apply (erule rev_subsetD)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6266	apply (rule c2)
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	6267	done
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6268	then have "continuous_on (ball x d) f"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6269	apply (rule_tac convex_on_bounded_continuous)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6270	apply (rule open_ball, rule convex_on_subset[OF conv])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6271	apply (rule ball_subset_cball)
33270 320a1d67b9ae merged paulson parents: 33175 diff changeset	6272	apply force
320a1d67b9ae merged paulson parents: 33175 diff changeset	6273	done
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6274	then show "continuous (at x) f"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6275	unfolding continuous_on_eq_continuous_at[OF open_ball]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6276	using `d > 0` by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6277	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6278
33270 320a1d67b9ae merged paulson parents: 33175 diff changeset	6279
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	6280	subsection {* Line segments, Starlike Sets, etc. *}
33270 320a1d67b9ae merged paulson parents: 33175 diff changeset	6281
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	6282	(* Use the same overloading tricks as for intervals, so that
33270 320a1d67b9ae merged paulson parents: 33175 diff changeset	6283	segment[a,b] is closed and segment(a,b) is open relative to affine hull. *)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6284
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6285	definition midpoint :: "'a::real_vector \<Rightarrow> 'a \<Rightarrow> 'a"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6286	where "midpoint a b = (inverse (2::real)) *\<^sub>R (a + b)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6287
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6288	definition open_segment :: "'a::real_vector \<Rightarrow> 'a \<Rightarrow> 'a set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6289	where "open_segment a b = {(1 - u) \<^sub>R a + u \<^sub>R b \| u::real. 0 < u \<and> u < 1}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6290
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6291	definition closed_segment :: "'a::real_vector \<Rightarrow> 'a \<Rightarrow> 'a set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6292	where "closed_segment a b = {(1 - u) \<^sub>R a + u \<^sub>R b \| u::real. 0 \<le> u \<and> u \<le> 1}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6293
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6294	definition "between = (\<lambda>(a,b) x. x \<in> closed_segment a b)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6295
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6296	lemmas segment = open_segment_def closed_segment_def
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6297
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6298	definition "starlike s \<longleftrightarrow> (\<exists>a\<in>s. \<forall>x\<in>s. closed_segment a x \<subseteq> s)"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6299
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6300	lemma midpoint_refl: "midpoint x x = x"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6301	unfolding midpoint_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6302	unfolding scaleR_right_distrib
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6303	unfolding scaleR_left_distrib[symmetric]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6304	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6305
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6306	lemma midpoint_sym: "midpoint a b = midpoint b a"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6307	unfolding midpoint_def by (auto simp add: scaleR_right_distrib)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6308
36338 7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	6309	lemma midpoint_eq_iff: "midpoint a b = c \<longleftrightarrow> a + b = c + c"
7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	6310	proof -
7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	6311	have "midpoint a b = c \<longleftrightarrow> scaleR 2 (midpoint a b) = scaleR 2 c"
7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	6312	by simp
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6313	then show ?thesis
36338 7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	6314	unfolding midpoint_def scaleR_2 [symmetric] by simp
7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	6315	qed
7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	6316
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6317	lemma dist_midpoint:
36338 7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	6318	fixes a b :: "'a::real_normed_vector" shows
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6319	"dist a (midpoint a b) = (dist a b) / 2" (is ?t1)
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6320	"dist b (midpoint a b) = (dist a b) / 2" (is ?t2)
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6321	"dist (midpoint a b) a = (dist a b) / 2" (is ?t3)
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6322	"dist (midpoint a b) b = (dist a b) / 2" (is ?t4)
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6323	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6324	have : "\<And>x y::'a. 2 \<^sub>R x = - y \<Longrightarrow> norm x = (norm y) / 2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6325	unfolding equation_minus_iff by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6326	have *: "\<And>x y::'a. 2 \<^sub>R x = y \<Longrightarrow> norm x = (norm y) / 2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6327	by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6328	note scaleR_right_distrib [simp]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6329	show ?t1
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6330	unfolding midpoint_def dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6331	apply (rule **)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6332	apply (simp add: scaleR_right_diff_distrib)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6333	apply (simp add: scaleR_2)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6334	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6335	show ?t2
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6336	unfolding midpoint_def dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6337	apply (rule *)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6338	apply (simp add: scaleR_right_diff_distrib)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6339	apply (simp add: scaleR_2)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6340	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6341	show ?t3
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6342	unfolding midpoint_def dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6343	apply (rule *)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6344	apply (simp add: scaleR_right_diff_distrib)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6345	apply (simp add: scaleR_2)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6346	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6347	show ?t4
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6348	unfolding midpoint_def dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6349	apply (rule **)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6350	apply (simp add: scaleR_right_diff_distrib)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6351	apply (simp add: scaleR_2)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6352	done
36338 7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	6353	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6354
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6355	lemma midpoint_eq_endpoint:
36338 7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	6356	"midpoint a b = a \<longleftrightarrow> a = b"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6357	"midpoint a b = b \<longleftrightarrow> a = b"
36338 7808fbc9c3b4 generalize more constants and lemmas huffman parents: 36337 diff changeset	6358	unfolding midpoint_eq_iff by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6359
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6360	lemma convex_contains_segment:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6361	"convex s \<longleftrightarrow> (\<forall>a\<in>s. \<forall>b\<in>s. closed_segment a b \<subseteq> s)"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6362	unfolding convex_alt closed_segment_def by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6363
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6364	lemma convex_imp_starlike:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6365	"convex s \<Longrightarrow> s \<noteq> {} \<Longrightarrow> starlike s"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6366	unfolding convex_contains_segment starlike_def by auto
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6367
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6368	lemma segment_convex_hull:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6369	"closed_segment a b = convex hull {a,b}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6370	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6371	have *: "\<And>x. {x} \<noteq> {}" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6372	have **: "\<And>u v. u + v = 1 \<longleftrightarrow> u = 1 - (v::real)" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6373	show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6374	unfolding segment convex_hull_insert[OF *] convex_hull_singleton
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6375	apply (rule set_eqI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6376	unfolding mem_Collect_eq
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6377	apply (rule, erule exE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6378	apply (rule_tac x="1 - u" in exI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6379	apply rule
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6380	defer
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6381	apply (rule_tac x=u in exI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6382	defer
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6383	apply (elim exE conjE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6384	apply (rule_tac x="1 - u" in exI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6385	unfolding **
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6386	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6387	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6388	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6389
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6390	lemma convex_segment: "convex (closed_segment a b)"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6391	unfolding segment_convex_hull by(rule convex_convex_hull)
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6392
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6393	lemma ends_in_segment: "a \<in> closed_segment a b" "b \<in> closed_segment a b"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6394	unfolding segment_convex_hull
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6395	apply (rule_tac[!] hull_subset[unfolded subset_eq, rule_format])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6396	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6397	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6398
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6399	lemma segment_furthest_le:
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	6400	fixes a b x y :: "'a::euclidean_space"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6401	assumes "x \<in> closed_segment a b"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6402	shows "norm (y - x) \<le> norm (y - a) \<or> norm (y - x) \<le> norm (y - b)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6403	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6404	obtain z where "z \<in> {a, b}" "norm (x - y) \<le> norm (z - y)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6405	using simplex_furthest_le[of "{a, b}" y]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6406	using assms[unfolded segment_convex_hull]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6407	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6408	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6409	by (auto simp add:norm_minus_commute)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6410	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6411
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6412	lemma segment_bound:
37489 44e42d392c6e Introduce a type class for euclidean spaces, port most lemmas from real^'n to this type class. hoelzl parents: 36844 diff changeset	6413	fixes x a b :: "'a::euclidean_space"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6414	assumes "x \<in> closed_segment a b"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6415	shows "norm (x - a) \<le> norm (b - a)" "norm (x - b) \<le> norm (b - a)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6416	using segment_furthest_le[OF assms, of a]
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6417	using segment_furthest_le[OF assms, of b]
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	6418	by (auto simp add:norm_minus_commute)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6419
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6420	lemma segment_refl: "closed_segment a a = {a}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6421	unfolding segment by (auto simp add: algebra_simps)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6422
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6423	lemma between_mem_segment: "between (a,b) x \<longleftrightarrow> x \<in> closed_segment a b"
44170 510ac30f44c0 make Multivariate_Analysis work with separate set type huffman parents: 44142 diff changeset	6424	unfolding between_def by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6425
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6426	lemma between: "between (a, b) (x::'a::euclidean_space) \<longleftrightarrow> dist a b = (dist a x) + (dist x b)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6427	proof (cases "a = b")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6428	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6429	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6430	unfolding between_def split_conv
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6431	by (auto simp add:segment_refl dist_commute)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6432	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6433	case False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6434	then have Fal: "norm (a - b) \<noteq> 0" and Fal2: "norm (a - b) > 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6435	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6436	have : "\<And>u. a - ((1 - u) \<^sub>R a + u \<^sub>R b) = u \<^sub>R (a - b)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6437	by (auto simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6438	show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6439	unfolding between_def split_conv closed_segment_def mem_Collect_eq
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6440	apply rule
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6441	apply (elim exE conjE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6442	apply (subst dist_triangle_eq)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6443	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6444	fix u
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6445	assume as: "x = (1 - u) \<^sub>R a + u \<^sub>R b" "0 \<le> u" "u \<le> 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6446	then have : "a - x = u \<^sub>R (a - b)" "x - b = (1 - u) *\<^sub>R (a - b)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6447	unfolding as(1) by (auto simp add:algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6448	show "norm (a - x) \<^sub>R (x - b) = norm (x - b) \<^sub>R (a - x)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6449	unfolding norm_minus_commute[of x a] * using as(2,3)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6450	by (auto simp add: field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6451	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6452	assume as: "dist a b = dist a x + dist x b"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6453	have "norm (a - x) / norm (a - b) \<le> 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6454	unfolding divide_le_eq_1_pos[OF Fal2]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6455	unfolding as[unfolded dist_norm] norm_ge_zero
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6456	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6457	then show "\<exists>u. x = (1 - u) \<^sub>R a + u \<^sub>R b \<and> 0 \<le> u \<and> u \<le> 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6458	apply (rule_tac x="dist a x / dist a b" in exI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6459	unfolding dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6460	apply (subst euclidean_eq_iff)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6461	apply rule
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6462	defer
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6463	apply rule
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6464	apply (rule divide_nonneg_pos)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6465	prefer 4
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6466	apply rule
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6467	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6468	fix i :: 'a
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6469	assume i: "i \<in> Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6470	have "((1 - norm (a - x) / norm (a - b)) \<^sub>R a + (norm (a - x) / norm (a - b)) \<^sub>R b) \<bullet> i =
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6471	((norm (a - b) - norm (a - x)) * (a \<bullet> i) + norm (a - x) * (b \<bullet> i)) / norm (a - b)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6472	using Fal by (auto simp add: field_simps inner_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6473	also have "\<dots> = x\<bullet>i"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6474	apply (rule divide_eq_imp[OF Fal])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6475	unfolding as[unfolded dist_norm]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6476	using as[unfolded dist_triangle_eq]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6477	apply -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6478	apply (subst (asm) euclidean_eq_iff)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6479	using i
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6480	apply (erule_tac x=i in ballE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6481	apply (auto simp add:field_simps inner_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6482	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6483	finally show "x \<bullet> i =
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6484	((1 - norm (a - x) / norm (a - b)) \<^sub>R a + (norm (a - x) / norm (a - b)) \<^sub>R b) \<bullet> i"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6485	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6486	qed (insert Fal2, auto)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6487	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6488	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6489
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6490	lemma between_midpoint:
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6491	fixes a :: "'a::euclidean_space"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6492	shows "between (a,b) (midpoint a b)" (is ?t1)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6493	and "between (b,a) (midpoint a b)" (is ?t2)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6494	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6495	have : "\<And>x y z. x = (1/2::real) \<^sub>R z \<Longrightarrow> y = (1/2) *\<^sub>R z \<Longrightarrow> norm z = norm x + norm y"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6496	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6497	show ?t1 ?t2
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6498	unfolding between midpoint_def dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6499	apply(rule_tac[!] *)
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6500	unfolding euclidean_eq_iff[where 'a='a]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6501	apply (auto simp add: field_simps inner_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6502	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6503	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6504
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6505	lemma between_mem_convex_hull:
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6506	"between (a,b) x \<longleftrightarrow> x \<in> convex hull {a,b}"
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6507	unfolding between_mem_segment segment_convex_hull ..
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6508
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6509
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	6510	subsection {* Shrinking towards the interior of a convex set *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6511
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6512	lemma mem_interior_convex_shrink:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6513	fixes s :: "'a::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6514	assumes "convex s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6515	and "c \<in> interior s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6516	and "x \<in> s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6517	and "0 < e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6518	and "e \<le> 1"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6519	shows "x - e *\<^sub>R (x - c) \<in> interior s"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6520	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6521	obtain d where "d > 0" and d: "ball c d \<subseteq> s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6522	using assms(2) unfolding mem_interior by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6523	show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6524	unfolding mem_interior
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6525	apply (rule_tac x="e*d" in exI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6526	apply rule
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6527	defer
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6528	unfolding subset_eq Ball_def mem_ball
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6529	proof (rule, rule)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6530	fix y
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6531	assume as: "dist (x - e \<^sub>R (x - c)) y < e d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6532	have : "y = (1 - (1 - e)) \<^sub>R ((1 / e) \<^sub>R y - ((1 - e) / e) \<^sub>R x) + (1 - e) *\<^sub>R x"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6533	using `e > 0` by (auto simp add: scaleR_left_diff_distrib scaleR_right_diff_distrib)
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6534	have "dist c ((1 / e) \<^sub>R y - ((1 - e) / e) \<^sub>R x) = abs(1/e) * norm (e \<^sub>R c - y + (1 - e) \<^sub>R x)"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6535	unfolding dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6536	unfolding norm_scaleR[symmetric]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6537	apply (rule arg_cong[where f=norm])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6538	using `e > 0`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6539	by (auto simp add: euclidean_eq_iff[where 'a='a] field_simps inner_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6540	also have "\<dots> = abs (1/e) * norm (x - e *\<^sub>R (x - c) - y)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6541	by (auto intro!:arg_cong[where f=norm] simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6542	also have "\<dots> < d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6543	using as[unfolded dist_norm] and `e > 0`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6544	by (auto simp add:pos_divide_less_eq[OF `e > 0`] mult_commute)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6545	finally show "y \<in> s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6546	apply (subst *)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6547	apply (rule assms(1)[unfolded convex_alt,rule_format])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6548	apply (rule d[unfolded subset_eq,rule_format])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6549	unfolding mem_ball
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6550	using assms(3-5)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6551	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6552	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6553	qed (rule mult_pos_pos, insert `e>0` `d>0`, auto)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6554	qed
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6555
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6556	lemma mem_interior_closure_convex_shrink:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6557	fixes s :: "'a::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6558	assumes "convex s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6559	and "c \<in> interior s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6560	and "x \<in> closure s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6561	and "0 < e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6562	and "e \<le> 1"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6563	shows "x - e *\<^sub>R (x - c) \<in> interior s"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6564	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6565	obtain d where "d > 0" and d: "ball c d \<subseteq> s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6566	using assms(2) unfolding mem_interior by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6567	have "\<exists>y\<in>s. norm (y - x) * (1 - e) < e * d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6568	proof (cases "x \<in> s")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6569	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6570	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6571	using `e > 0` `d > 0`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6572	apply (rule_tac bexI[where x=x])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6573	apply (auto intro!: mult_pos_pos)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6574	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6575	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6576	case False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6577	then have x: "x islimpt s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6578	using assms(3)[unfolded closure_def] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6579	show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6580	proof (cases "e = 1")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6581	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6582	obtain y where "y \<in> s" "y \<noteq> x" "dist y x < 1"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6583	using x[unfolded islimpt_approachable,THEN spec[where x=1]] by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6584	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6585	apply (rule_tac x=y in bexI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6586	unfolding True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6587	using `d > 0`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6588	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6589	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6590	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6591	case False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6592	then have "0 < e * d / (1 - e)" and *: "1 - e > 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6593	using `e \<le> 1` `e > 0` `d > 0`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6594	by (auto intro!:mult_pos_pos divide_pos_pos)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6595	then obtain y where "y \<in> s" "y \<noteq> x" "dist y x < e * d / (1 - e)"
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6596	using x[unfolded islimpt_approachable,THEN spec[where x="e*d / (1 - e)"]] by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6597	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6598	apply (rule_tac x=y in bexI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6599	unfolding dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6600	using pos_less_divide_eq[OF *]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6601	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6602	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6603	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6604	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6605	then obtain y where "y \<in> s" and y: "norm (y - x) * (1 - e) < e * d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6606	by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6607	def z \<equiv> "c + ((1 - e) / e) *\<^sub>R (x - y)"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6608	have : "x - e \<^sub>R (x - c) = y - e *\<^sub>R (y - z)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6609	unfolding z_def using `e > 0`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6610	by (auto simp add: scaleR_right_diff_distrib scaleR_right_distrib scaleR_left_diff_distrib)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6611	have "z \<in> interior s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6612	apply (rule interior_mono[OF d,unfolded subset_eq,rule_format])
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6613	unfolding interior_open[OF open_ball] mem_ball z_def dist_norm using y and assms(4,5)
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6614	apply (auto simp add:field_simps norm_minus_commute)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6615	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6616	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6617	unfolding *
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6618	apply -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6619	apply (rule mem_interior_convex_shrink)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6620	using assms(1,4-5) `y\<in>s`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6621	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6622	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6623	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6624
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6625
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	6626	subsection {* Some obvious but surprisingly hard simplex lemmas *}
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6627
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6628	lemma simplex:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6629	assumes "finite s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6630	and "0 \<notin> s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6631	shows "convex hull (insert 0 s) =
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6632	{y. (\<exists>u. (\<forall>x\<in>s. 0 \<le> u x) \<and> setsum u s \<le> 1 \<and> setsum (\<lambda>x. u x *\<^sub>R x) s = y)}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6633	unfolding convex_hull_finite[OF finite.insertI[OF assms(1)]]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6634	apply (rule set_eqI, rule)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6635	unfolding mem_Collect_eq
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6636	apply (erule_tac[!] exE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6637	apply (erule_tac[!] conjE)+
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6638	unfolding setsum_clauses(2)[OF assms(1)]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6639	apply (rule_tac x=u in exI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6640	defer
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6641	apply (rule_tac x="\<lambda>x. if x = 0 then 1 - setsum u s else u x" in exI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6642	using assms(2)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6643	unfolding if_smult and setsum_delta_notmem[OF assms(2)]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6644	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6645	done
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6646
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6647	lemma substd_simplex:
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6648	assumes d: "d \<subseteq> Basis"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6649	shows "convex hull (insert 0 d) =
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	6650	{x. (\<forall>i\<in>Basis. 0 \<le> x\<bullet>i) \<and> (\<Sum>i\<in>d. x\<bullet>i) \<le> 1 \<and> (\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x\<bullet>i = 0)}"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	6651	(is "convex hull (insert 0 ?p) = ?s")
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6652	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6653	let ?D = d
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6654	have "0 \<notin> ?p"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6655	using assms by (auto simp: image_def)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6656	from d have "finite d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6657	by (blast intro: finite_subset finite_Basis)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6658	show ?thesis
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	6659	unfolding simplex[OF `finite d` `0 \<notin> ?p`]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6660	apply (rule set_eqI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6661	unfolding mem_Collect_eq
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6662	apply rule
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6663	apply (elim exE conjE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6664	apply (erule_tac[2] conjE)+
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6665	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6666	fix x :: "'a::euclidean_space"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6667	fix u
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6668	assume as: "\<forall>x\<in>?D. 0 \<le> u x" "setsum u ?D \<le> 1" "(\<Sum>x\<in>?D. u x *\<^sub>R x) = x"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6669	have *: "\<forall>i\<in>Basis. i:d \<longrightarrow> u i = x\<bullet>i"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	6670	and "(\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x \<bullet> i = 0)"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6671	using as(3)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6672	unfolding substdbasis_expansion_unique[OF assms]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6673	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6674	then have **: "setsum u ?D = setsum (op \<bullet> x) ?D"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6675	apply -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6676	apply (rule setsum_cong2)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6677	using assms
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6678	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6679	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6680	have "(\<forall>i\<in>Basis. 0 \<le> x\<bullet>i) \<and> setsum (op \<bullet> x) ?D \<le> 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6681	proof (rule,rule)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6682	fix i :: 'a
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6683	assume i: "i \<in> Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6684	have "i \<in> d \<Longrightarrow> 0 \<le> x\<bullet>i"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6685	unfolding *[rule_format,OF i,symmetric]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6686	apply (rule_tac as(1)[rule_format])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6687	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6688	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6689	moreover have "i \<notin> d \<Longrightarrow> 0 \<le> x\<bullet>i"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6690	using `(\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x \<bullet> i = 0)`[rule_format, OF i] by auto
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6691	ultimately show "0 \<le> x\<bullet>i" by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6692	qed (insert as(2)[unfolded **], auto)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6693	then show "(\<forall>i\<in>Basis. 0 \<le> x\<bullet>i) \<and> setsum (op \<bullet> x) ?D \<le> 1 \<and> (\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x \<bullet> i = 0)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6694	using `(\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x \<bullet> i = 0)` by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6695	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6696	fix x :: "'a::euclidean_space"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6697	assume as: "\<forall>i\<in>Basis. 0 \<le> x \<bullet> i" "setsum (op \<bullet> x) ?D \<le> 1" "(\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x \<bullet> i = 0)"
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6698	show "\<exists>u. (\<forall>x\<in>?D. 0 \<le> u x) \<and> setsum u ?D \<le> 1 \<and> (\<Sum>x\<in>?D. u x *\<^sub>R x) = x"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6699	using as d
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6700	unfolding substdbasis_expansion_unique[OF assms]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6701	apply (rule_tac x="inner x" in exI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6702	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6703	done
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6704	qed
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6705	qed
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	6706
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6707	lemma std_simplex:
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6708	"convex hull (insert 0 Basis) =
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6709	{x::'a::euclidean_space. (\<forall>i\<in>Basis. 0 \<le> x\<bullet>i) \<and> setsum (\<lambda>i. x\<bullet>i) Basis \<le> 1}"
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6710	using substd_simplex[of Basis] by auto
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6711
2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6712	lemma interior_std_simplex:
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6713	"interior (convex hull (insert 0 Basis)) =
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6714	{x::'a::euclidean_space. (\<forall>i\<in>Basis. 0 < x\<bullet>i) \<and> setsum (\<lambda>i. x\<bullet>i) Basis < 1}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6715	apply (rule set_eqI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6716	unfolding mem_interior std_simplex
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6717	unfolding subset_eq mem_Collect_eq Ball_def mem_ball
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6718	unfolding Ball_def[symmetric]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6719	apply rule
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6720	apply (elim exE conjE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6721	defer
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6722	apply (erule conjE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6723	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6724	fix x :: 'a
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6725	fix e
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6726	assume "e > 0" and as: "\<forall>xa. dist x xa < e \<longrightarrow> (\<forall>x\<in>Basis. 0 \<le> xa \<bullet> x) \<and> setsum (op \<bullet> xa) Basis \<le> 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6727	show "(\<forall>xa\<in>Basis. 0 < x \<bullet> xa) \<and> setsum (op \<bullet> x) Basis < 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6728	apply safe
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6729	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6730	fix i :: 'a
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6731	assume i: "i \<in> Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6732	then show "0 < x \<bullet> i"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6733	using as[THEN spec[where x="x - (e / 2) *\<^sub>R i"]] and `e > 0`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6734	unfolding dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6735	by (auto elim!: ballE[where x=i] simp: inner_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6736	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6737	have *: "dist x (x + (e / 2) \<^sub>R (SOME i. i\<in>Basis)) < e" using `e > 0`
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6738	unfolding dist_norm
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6739	by (auto intro!: mult_strict_left_mono simp: SOME_Basis)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6740	have "\<And>i. i \<in> Basis \<Longrightarrow> (x + (e / 2) *\<^sub>R (SOME i. i\<in>Basis)) \<bullet> i =
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6741	x\<bullet>i + (if i = (SOME i. i\<in>Basis) then e/2 else 0)"
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6742	by (auto simp: SOME_Basis inner_Basis inner_simps)
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6743	then have : "setsum (op \<bullet> (x + (e / 2) \<^sub>R (SOME i. i\<in>Basis))) Basis =
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6744	setsum (\<lambda>i. x\<bullet>i + (if (SOME i. i\<in>Basis) = i then e/2 else 0)) Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6745	apply (rule_tac setsum_cong)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6746	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6747	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6748	have "setsum (op \<bullet> x) Basis < setsum (op \<bullet> (x + (e / 2) *\<^sub>R (SOME i. i\<in>Basis))) Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6749	unfolding * setsum_addf
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6750	using `e > 0` DIM_positive[where 'a='a]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6751	apply (subst setsum_delta')
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6752	apply (auto simp: SOME_Basis)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6753	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6754	also have "\<dots> \<le> 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6755	using **
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6756	apply (drule_tac as[rule_format])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6757	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6758	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6759	finally show "setsum (op \<bullet> x) Basis < 1" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6760	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6761	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6762	fix x :: 'a
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6763	assume as: "\<forall>i\<in>Basis. 0 < x \<bullet> i" "setsum (op \<bullet> x) Basis < 1"
55697 abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	6764	obtain a :: 'b where "a \<in> UNIV" using UNIV_witness ..
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6765	let ?d = "(1 - setsum (op \<bullet> x) Basis) / real (DIM('a))"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6766	have "Min ((op \<bullet> x) ` Basis) > 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6767	apply (rule Min_grI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6768	using as(1)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6769	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6770	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6771	moreover have "?d > 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6772	apply (rule divide_pos_pos)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6773	using as(2)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6774	apply (auto simp add: Suc_le_eq DIM_positive)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6775	done
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6776	ultimately show "\<exists>e>0. \<forall>y. dist x y < e \<longrightarrow> (\<forall>i\<in>Basis. 0 \<le> y \<bullet> i) \<and> setsum (op \<bullet> y) Basis \<le> 1"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6777	apply (rule_tac x="min (Min ((op \<bullet> x) ` Basis)) ?D" in exI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6778	apply rule
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6779	defer
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6780	apply (rule, rule)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6781	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6782	fix y
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6783	assume y: "dist x y < min (Min (op \<bullet> x ` Basis)) ?d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6784	have "setsum (op \<bullet> y) Basis \<le> setsum (\<lambda>i. x\<bullet>i + ?d) Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6785	proof (rule setsum_mono)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6786	fix i :: 'a
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6787	assume i: "i \<in> Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6788	then have "abs (y\<bullet>i - x\<bullet>i) < ?d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6789	apply -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6790	apply (rule le_less_trans)
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6791	using Basis_le_norm[OF i, of "y - x"]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6792	using y[unfolded min_less_iff_conj dist_norm, THEN conjunct2]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6793	apply (auto simp add: norm_minus_commute inner_diff_left)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6794	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6795	then show "y \<bullet> i \<le> x \<bullet> i + ?d" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6796	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6797	also have "\<dots> \<le> 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6798	unfolding setsum_addf setsum_constant real_eq_of_nat
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6799	by (auto simp add: Suc_le_eq)
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6800	finally show "(\<forall>i\<in>Basis. 0 \<le> y \<bullet> i) \<and> setsum (op \<bullet> y) Basis \<le> 1"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6801	proof safe
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6802	fix i :: 'a
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6803	assume i: "i \<in> Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6804	have "norm (x - y) < x\<bullet>i"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6805	apply (rule less_le_trans)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6806	apply (rule y[unfolded min_less_iff_conj dist_norm, THEN conjunct1])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6807	using i
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6808	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6809	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6810	then show "0 \<le> y\<bullet>i"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6811	using Basis_le_norm[OF i, of "x - y"] and as(1)[rule_format, OF i]
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6812	by (auto simp: inner_simps)
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6813	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6814	qed auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6815	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6816
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6817	lemma interior_std_simplex_nonempty:
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6818	obtains a :: "'a::euclidean_space" where
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6819	"a \<in> interior(convex hull (insert 0 Basis))"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6820	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6821	let ?D = "Basis :: 'a set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6822	let ?a = "setsum (\<lambda>b::'a. inverse (2 * real DIM('a)) *\<^sub>R b) Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6823	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6824	fix i :: 'a
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6825	assume i: "i \<in> Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6826	have "?a \<bullet> i = inverse (2 * real DIM('a))"
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6827	by (rule trans[of _ "setsum (\<lambda>j. if i = j then inverse (2 * real DIM('a)) else 0) ?D"])
899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	6828	(simp_all add: setsum_cases i) }
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	6829	note ** = this
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6830	show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6831	apply (rule that[of ?a])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6832	unfolding interior_std_simplex mem_Collect_eq
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6833	proof safe
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6834	fix i :: 'a
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6835	assume i: "i \<in> Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6836	show "0 < ?a \<bullet> i"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6837	unfolding **[OF i] by (auto simp add: Suc_le_eq DIM_positive)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6838	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6839	have "setsum (op \<bullet> ?a) ?D = setsum (\<lambda>i. inverse (2 * real DIM('a))) ?D"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6840	apply (rule setsum_cong2, rule **)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6841	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6842	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6843	also have "\<dots> < 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6844	unfolding setsum_constant real_eq_of_nat divide_inverse[symmetric]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6845	by (auto simp add: field_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6846	finally show "setsum (op \<bullet> ?a) ?D < 1" by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	6847	qed
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6848	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6849
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6850	lemma rel_interior_substd_simplex:
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6851	assumes d: "d \<subseteq> Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6852	shows "rel_interior (convex hull (insert 0 d)) =
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6853	{x::'a::euclidean_space. (\<forall>i\<in>d. 0 < x\<bullet>i) \<and> (\<Sum>i\<in>d. x\<bullet>i) < 1 \<and> (\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x\<bullet>i = 0)}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6854	(is "rel_interior (convex hull (insert 0 ?p)) = ?s")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6855	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6856	have "finite d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6857	apply (rule finite_subset)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6858	using assms
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6859	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6860	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6861	show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6862	proof (cases "d = {}")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6863	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6864	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6865	using rel_interior_sing using euclidean_eq_iff[of _ 0] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6866	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6867	case False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6868	have h0: "affine hull (convex hull (insert 0 ?p)) =
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6869	{x::'a::euclidean_space. (\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x\<bullet>i = 0)}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6870	using affine_hull_convex_hull affine_hull_substd_basis assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6871	have aux: "\<And>x::'a. \<forall>i\<in>Basis. (\<forall>i\<in>d. 0 \<le> x\<bullet>i) \<and> (\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x\<bullet>i = 0) \<longrightarrow> 0 \<le> x\<bullet>i"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6872	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6873	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6874	fix x :: "'a::euclidean_space"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6875	assume x: "x \<in> rel_interior (convex hull (insert 0 ?p))"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6876	then obtain e where e0: "e > 0" and
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6877	"ball x e \<inter> {xa. (\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> xa\<bullet>i = 0)} \<subseteq> convex hull (insert 0 ?p)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6878	using mem_rel_interior_ball[of x "convex hull (insert 0 ?p)"] h0 by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6879	then have as: "\<forall>xa. dist x xa < e \<and> (\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> xa\<bullet>i = 0) \<longrightarrow>
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6880	(\<forall>i\<in>d. 0 \<le> xa \<bullet> i) \<and> setsum (op \<bullet> xa) d \<le> 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6881	unfolding ball_def unfolding substd_simplex[OF assms] using assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6882	have x0: "(\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x\<bullet>i = 0)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6883	using x rel_interior_subset substd_simplex[OF assms] by auto
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	6884	have "(\<forall>i\<in>d. 0 < x \<bullet> i) \<and> setsum (op \<bullet> x) d < 1 \<and> (\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x\<bullet>i = 0)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	6885	apply rule
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	6886	apply rule
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6887	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6888	fix i :: 'a
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6889	assume "i \<in> d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6890	then have "\<forall>ia\<in>d. 0 \<le> (x - (e / 2) *\<^sub>R i) \<bullet> ia"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6891	apply -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6892	apply (rule as[rule_format,THEN conjunct1])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6893	unfolding dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6894	using d `e > 0` x0
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6895	apply (auto simp: inner_simps inner_Basis)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6896	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6897	then show "0 < x \<bullet> i"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6898	apply (erule_tac x=i in ballE)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6899	using `e > 0` `i \<in> d` d
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6900	apply (auto simp: inner_simps inner_Basis)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6901	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6902	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6903	obtain a where a: "a \<in> d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6904	using `d \<noteq> {}` by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6905	then have *: "dist x (x + (e / 2) \<^sub>R a) < e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6906	using `e > 0` norm_Basis[of a] d
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6907	unfolding dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6908	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6909	have "\<And>i. i \<in> Basis \<Longrightarrow> (x + (e / 2) *\<^sub>R a) \<bullet> i = x\<bullet>i + (if i = a then e/2 else 0)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6910	using a d by (auto simp: inner_simps inner_Basis)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6911	then have : "setsum (op \<bullet> (x + (e / 2) \<^sub>R a)) d =
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6912	setsum (\<lambda>i. x\<bullet>i + (if a = i then e/2 else 0)) d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6913	using d by (intro setsum_cong) auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6914	have "a \<in> Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6915	using `a \<in> d` d by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6916	then have h1: "(\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> (x + (e / 2) *\<^sub>R a) \<bullet> i = 0)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6917	using x0 d `a\<in>d` by (auto simp add: inner_add_left inner_Basis)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6918	have "setsum (op \<bullet> x) d < setsum (op \<bullet> (x + (e / 2) *\<^sub>R a)) d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6919	unfolding * setsum_addf
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6920	using `e > 0` `a \<in> d`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6921	using `finite d`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6922	by (auto simp add: setsum_delta')
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6923	also have "\<dots> \<le> 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6924	using ** h1 as[rule_format, of "x + (e / 2) *\<^sub>R a"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6925	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6926	finally show "setsum (op \<bullet> x) d < 1 \<and> (\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x\<bullet>i = 0)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6927	using x0 by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6928	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6929	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6930	moreover
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6931	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6932	fix x :: "'a::euclidean_space"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6933	assume as: "x \<in> ?s"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6934	have "\<forall>i. 0 < x\<bullet>i \<or> 0 = x\<bullet>i \<longrightarrow> 0 \<le> x\<bullet>i"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6935	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6936	moreover have "\<forall>i. i \<in> d \<or> i \<notin> d" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6937	ultimately
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	6938	have "\<forall>i. (\<forall>i\<in>d. 0 < x\<bullet>i) \<and> (\<forall>i. i \<notin> d \<longrightarrow> x\<bullet>i = 0) \<longrightarrow> 0 \<le> x\<bullet>i"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6939	by metis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6940	then have h2: "x \<in> convex hull (insert 0 ?p)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6941	using as assms
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6942	unfolding substd_simplex[OF assms] by fastforce
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6943	obtain a where a: "a \<in> d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6944	using `d \<noteq> {}` by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6945	let ?d = "(1 - setsum (op \<bullet> x) d) / real (card d)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6946	have "0 < card d" using `d \<noteq> {}` `finite d`
44466 0e5c27f07529 remove unnecessary lemma card_ge1 huffman parents: 44465 diff changeset	6947	by (simp add: card_gt_0_iff)
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6948	have "Min ((op \<bullet> x) ` d) > 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6949	using as `d \<noteq> {}` `finite d` by (simp add: Min_grI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6950	moreover have "?d > 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6951	apply (rule divide_pos_pos)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6952	using as using `0 < card d` by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6953	ultimately have h3: "min (Min ((op \<bullet> x) ` d)) ?d > 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6954	by auto
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	6955
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6956	have "x \<in> rel_interior (convex hull (insert 0 ?p))"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6957	unfolding rel_interior_ball mem_Collect_eq h0
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6958	apply (rule,rule h2)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6959	unfolding substd_simplex[OF assms]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6960	apply (rule_tac x="min (Min ((op \<bullet> x) ` d)) ?d" in exI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6961	apply (rule, rule h3)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6962	apply safe
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6963	unfolding mem_ball
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6964	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6965	fix y :: 'a
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6966	assume y: "dist x y < min (Min (op \<bullet> x ` d)) ?d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6967	assume y2: "\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> y\<bullet>i = 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6968	have "setsum (op \<bullet> y) d \<le> setsum (\<lambda>i. x\<bullet>i + ?d) d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6969	proof (rule setsum_mono)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6970	fix i
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6971	assume "i \<in> d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6972	with d have i: "i \<in> Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6973	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6974	have "abs (y\<bullet>i - x\<bullet>i) < ?d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6975	apply (rule le_less_trans)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6976	using Basis_le_norm[OF i, of "y - x"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6977	using y[unfolded min_less_iff_conj dist_norm, THEN conjunct2]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6978	apply (auto simp add: norm_minus_commute inner_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6979	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6980	then show "y \<bullet> i \<le> x \<bullet> i + ?d" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6981	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6982	also have "\<dots> \<le> 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6983	unfolding setsum_addf setsum_constant real_eq_of_nat
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6984	using `0 < card d`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6985	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6986	finally show "setsum (op \<bullet> y) d \<le> 1" .
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	6987
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6988	fix i :: 'a
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6989	assume i: "i \<in> Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6990	then show "0 \<le> y\<bullet>i"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6991	proof (cases "i\<in>d")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6992	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6993	have "norm (x - y) < x\<bullet>i"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6994	using y[unfolded min_less_iff_conj dist_norm, THEN conjunct1]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6995	using Min_gr_iff[of "op \<bullet> x ` d" "norm (x - y)"] `0 < card d` `i:d`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6996	by (simp add: card_gt_0_iff)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6997	then show "0 \<le> y\<bullet>i"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6998	using Basis_le_norm[OF i, of "x - y"] and as(1)[rule_format]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	6999	by (auto simp: inner_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7000	qed (insert y2, auto)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7001	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7002	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7003	ultimately have
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7004	"\<And>x. x \<in> rel_interior (convex hull insert 0 d) \<longleftrightarrow>
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7005	x \<in> {x. (\<forall>i\<in>d. 0 < x \<bullet> i) \<and> setsum (op \<bullet> x) d < 1 \<and> (\<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x \<bullet> i = 0)}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7006	by blast
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7007	then show ?thesis by (rule set_eqI)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7008	qed
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7009	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7010
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7011	lemma rel_interior_substd_simplex_nonempty:
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7012	assumes "d \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7013	and "d \<subseteq> Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7014	obtains a :: "'a::euclidean_space"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7015	where "a \<in> rel_interior (convex hull (insert 0 d))"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7016	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7017	let ?D = d
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7018	let ?a = "setsum (\<lambda>b::'a::euclidean_space. inverse (2 * real (card d)) *\<^sub>R b) ?D"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7019	have "finite d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7020	apply (rule finite_subset)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7021	using assms(2)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7022	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7023	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7024	then have d1: "0 < real (card d)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7025	using `d \<noteq> {}` by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7026	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7027	fix i
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7028	assume "i \<in> d"
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	7029	have "?a \<bullet> i = inverse (2 * real (card d))"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7030	apply (rule trans[of _ "setsum (\<lambda>j. if i = j then inverse (2 * real (card d)) else 0) ?D"])
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	7031	unfolding inner_setsum_left
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7032	apply (rule setsum_cong2)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7033	using `i \<in> d` `finite d` setsum_delta'[of d i "(\<lambda>k. inverse (2 * real (card d)))"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7034	d1 assms(2)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7035	by (auto simp: inner_simps inner_Basis set_rev_mp[OF _ assms(2)])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7036	}
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7037	note ** = this
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7038	show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7039	apply (rule that[of ?a])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7040	unfolding rel_interior_substd_simplex[OF assms(2)] mem_Collect_eq
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7041	proof safe
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7042	fix i
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7043	assume "i \<in> d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7044	have "0 < inverse (2 * real (card d))"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7045	using d1 by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7046	also have "\<dots> = ?a \<bullet> i" using **[of i] `i \<in> d`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7047	by auto
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	7048	finally show "0 < ?a \<bullet> i" by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7049	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7050	have "setsum (op \<bullet> ?a) ?D = setsum (\<lambda>i. inverse (2 * real (card d))) ?D"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7051	by (rule setsum_cong2) (rule **)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7052	also have "\<dots> < 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7053	unfolding setsum_constant real_eq_of_nat divide_real_def[symmetric]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7054	by (auto simp add: field_simps)
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	7055	finally show "setsum (op \<bullet> ?a) ?D < 1" by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7056	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7057	fix i
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7058	assume "i \<in> Basis" and "i \<notin> d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7059	have "?a \<in> span d"
56196 32b7eafc5a52 remove unnecessary finiteness assumptions from lemmas about setsum huffman parents: 56189 diff changeset	7060	proof (rule span_setsum[of d "(\<lambda>b. b /\<^sub>R (2 * real (card d)))" d])
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7061	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7062	fix x :: "'a::euclidean_space"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7063	assume "x \<in> d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7064	then have "x \<in> span d"
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	7065	using span_superset[of _ "d"] by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7066	then have "x /\<^sub>R (2 * real (card d)) \<in> span d"
50526 899c9c4e4a4c Remove the indexed basis from the definition of euclidean spaces and only use the set of Basis vectors hoelzl parents: 50104 diff changeset	7067	using span_mul[of x "d" "(inverse (real (card d)) / 2)"] by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7068	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7069	then show "\<forall>x\<in>d. x /\<^sub>R (2 * real (card d)) \<in> span d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7070	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7071	qed
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7072	then show "?a \<bullet> i = 0 "
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7073	using `i \<notin> d` unfolding span_substd_basis[OF assms(2)] using `i \<in> Basis` by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7074	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7075	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7076
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7077
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	7078	subsection {* Relative interior of convex set *}
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7079
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7080	lemma rel_interior_convex_nonempty_aux:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7081	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7082	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7083	and "0 \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7084	shows "rel_interior S \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7085	proof (cases "S = {0}")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7086	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7087	then show ?thesis using rel_interior_sing by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7088	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7089	case False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7090	obtain B where B: "independent B \<and> B \<le> S \<and> S \<le> span B \<and> card B = dim S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7091	using basis_exists[of S] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7092	then have "B \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7093	using B assms `S \<noteq> {0}` span_empty by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7094	have "insert 0 B \<le> span B"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7095	using subspace_span[of B] subspace_0[of "span B"] span_inc by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7096	then have "span (insert 0 B) \<le> span B"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7097	using span_span[of B] span_mono[of "insert 0 B" "span B"] by blast
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7098	then have "convex hull insert 0 B \<le> span B"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7099	using convex_hull_subset_span[of "insert 0 B"] by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7100	then have "span (convex hull insert 0 B) \<le> span B"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7101	using span_span[of B] span_mono[of "convex hull insert 0 B" "span B"] by blast
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7102	then have *: "span (convex hull insert 0 B) = span B"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7103	using span_mono[of B "convex hull insert 0 B"] hull_subset[of "insert 0 B"] by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7104	then have "span (convex hull insert 0 B) = span S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7105	using B span_mono[of B S] span_mono[of S "span B"] span_span[of B] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7106	moreover have "0 \<in> affine hull (convex hull insert 0 B)"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7107	using hull_subset[of "convex hull insert 0 B"] hull_subset[of "insert 0 B"] by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7108	ultimately have **: "affine hull (convex hull insert 0 B) = affine hull S"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7109	using affine_hull_span_0[of "convex hull insert 0 B"] affine_hull_span_0[of "S"]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7110	assms hull_subset[of S]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7111	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7112	obtain d and f :: "'n \<Rightarrow> 'n" where
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7113	fd: "card d = card B" "linear f" "f ` B = d"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7114	"f ` span B = {x. \<forall>i\<in>Basis. i \<notin> d \<longrightarrow> x \<bullet> i = (0::real)} \<and> inj_on f (span B)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7115	and d: "d \<subseteq> Basis"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7116	using basis_to_substdbasis_subspace_isomorphism[of B,OF _ ] B by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7117	then have "bounded_linear f"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7118	using linear_conv_bounded_linear by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7119	have "d \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7120	using fd B `B \<noteq> {}` by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7121	have "insert 0 d = f ` (insert 0 B)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7122	using fd linear_0 by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7123	then have "(convex hull (insert 0 d)) = f ` (convex hull (insert 0 B))"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7124	using convex_hull_linear_image[of f "(insert 0 d)"]
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	7125	convex_hull_linear_image[of f "(insert 0 B)"] `linear f`
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7126	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7127	moreover have "rel_interior (f ` (convex hull insert 0 B)) =
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7128	f ` rel_interior (convex hull insert 0 B)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7129	apply (rule rel_interior_injective_on_span_linear_image[of f "(convex hull insert 0 B)"])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7130	using `bounded_linear f` fd *
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7131	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7132	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7133	ultimately have "rel_interior (convex hull insert 0 B) \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7134	using rel_interior_substd_simplex_nonempty[OF `d \<noteq> {}` d]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7135	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7136	apply blast
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7137	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7138	moreover have "convex hull (insert 0 B) \<subseteq> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7139	using B assms hull_mono[of "insert 0 B" "S" "convex"] convex_hull_eq
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7140	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7141	ultimately show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7142	using subset_rel_interior[of "convex hull insert 0 B" S] ** by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7143	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7144
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7145	lemma rel_interior_convex_nonempty:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7146	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7147	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7148	shows "rel_interior S = {} \<longleftrightarrow> S = {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7149	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7150	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7151	assume "S \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7152	then obtain a where "a \<in> S" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7153	then have "0 \<in> op + (-a) ` S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7154	using assms exI[of "(\<lambda>x. x \<in> S \<and> - a + x = 0)" a] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7155	then have "rel_interior (op + (-a) ` S) \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7156	using rel_interior_convex_nonempty_aux[of "op + (-a) ` S"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7157	convex_translation[of S "-a"] assms
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7158	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7159	then have "rel_interior S \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7160	using rel_interior_translation by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7161	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7162	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7163	using rel_interior_empty by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7164	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7165
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7166	lemma convex_rel_interior:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7167	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7168	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7169	shows "convex (rel_interior S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7170	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7171	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7172	fix x y and u :: real
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7173	assume assm: "x \<in> rel_interior S" "y \<in> rel_interior S" "0 \<le> u" "u \<le> 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7174	then have "x \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7175	using rel_interior_subset by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7176	have "x - u *\<^sub>R (x-y) \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7177	proof (cases "0 = u")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7178	case False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7179	then have "0 < u" using assm by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7180	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7181	using assm rel_interior_convex_shrink[of S y x u] assms `x \<in> S` by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7182	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7183	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7184	then show ?thesis using assm by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7185	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7186	then have "(1 - u) \<^sub>R x + u \<^sub>R y \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7187	by (simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7188	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7189	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7190	unfolding convex_alt by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7191	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7192
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7193	lemma convex_closure_rel_interior:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7194	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7195	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7196	shows "closure (rel_interior S) = closure S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7197	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7198	have h1: "closure (rel_interior S) \<le> closure S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7199	using closure_mono[of "rel_interior S" S] rel_interior_subset[of S] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7200	show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7201	proof (cases "S = {}")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7202	case False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7203	then obtain a where a: "a \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7204	using rel_interior_convex_nonempty assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7205	{ fix x
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7206	assume x: "x \<in> closure S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7207	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7208	assume "x = a"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7209	then have "x \<in> closure (rel_interior S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7210	using a unfolding closure_def by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7211	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7212	moreover
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7213	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7214	assume "x \<noteq> a"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7215	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7216	fix e :: real
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7217	assume "e > 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7218	def e1 \<equiv> "min 1 (e/norm (x - a))"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7219	then have e1: "e1 > 0" "e1 \<le> 1" "e1 * norm (x - a) \<le> e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7220	using `x \<noteq> a` `e > 0` divide_pos_pos[of e] le_divide_eq[of e1 e "norm (x - a)"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7221	by simp_all
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7222	then have : "x - e1 \<^sub>R (x - a) : rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7223	using rel_interior_closure_convex_shrink[of S a x e1] assms x a e1_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7224	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7225	have "\<exists>y. y \<in> rel_interior S \<and> y \<noteq> x \<and> dist y x \<le> e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7226	apply (rule_tac x="x - e1 *\<^sub>R (x - a)" in exI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7227	using * e1 dist_norm[of "x - e1 *\<^sub>R (x - a)" x] `x \<noteq> a`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7228	apply simp
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7229	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7230	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7231	then have "x islimpt rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7232	unfolding islimpt_approachable_le by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7233	then have "x \<in> closure(rel_interior S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7234	unfolding closure_def by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7235	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7236	ultimately have "x \<in> closure(rel_interior S)" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7237	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7238	then show ?thesis using h1 by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7239	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7240	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7241	then have "rel_interior S = {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7242	using rel_interior_empty by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7243	then have "closure (rel_interior S) = {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7244	using closure_empty by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7245	with True show ?thesis by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7246	qed
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7247	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7248
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7249	lemma rel_interior_same_affine_hull:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7250	fixes S :: "'n::euclidean_space set"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7251	assumes "convex S"
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7252	shows "affine hull (rel_interior S) = affine hull S"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7253	by (metis assms closure_same_affine_hull convex_closure_rel_interior)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7254
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7255	lemma rel_interior_aff_dim:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7256	fixes S :: "'n::euclidean_space set"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7257	assumes "convex S"
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7258	shows "aff_dim (rel_interior S) = aff_dim S"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7259	by (metis aff_dim_affine_hull2 assms rel_interior_same_affine_hull)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7260
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7261	lemma rel_interior_rel_interior:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7262	fixes S :: "'n::euclidean_space set"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7263	assumes "convex S"
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7264	shows "rel_interior (rel_interior S) = rel_interior S"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7265	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7266	have "openin (subtopology euclidean (affine hull (rel_interior S))) (rel_interior S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7267	using opein_rel_interior[of S] rel_interior_same_affine_hull[of S] assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7268	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7269	using rel_interior_def by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7270	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7271
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7272	lemma rel_interior_rel_open:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7273	fixes S :: "'n::euclidean_space set"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7274	assumes "convex S"
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7275	shows "rel_open (rel_interior S)"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7276	unfolding rel_open_def using rel_interior_rel_interior assms by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7277
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7278	lemma convex_rel_interior_closure_aux:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7279	fixes x y z :: "'n::euclidean_space"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7280	assumes "0 < a" "0 < b" "(a + b) \<^sub>R z = a \<^sub>R x + b *\<^sub>R y"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7281	obtains e where "0 < e" "e \<le> 1" "z = y - e *\<^sub>R (y - x)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7282	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7283	def e \<equiv> "a / (a + b)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7284	have "z = (1 / (a + b)) \<^sub>R ((a + b) \<^sub>R z)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7285	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7286	using assms
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7287	apply simp
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7288	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7289	also have "\<dots> = (1 / (a + b)) \<^sub>R (a \<^sub>R x + b *\<^sub>R y)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7290	using assms scaleR_cancel_left[of "1/(a+b)" "(a + b) \<^sub>R z" "a \<^sub>R x + b *\<^sub>R y"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7291	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7292	also have "\<dots> = y - e *\<^sub>R (y-x)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7293	using e_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7294	apply (simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7295	using scaleR_left_distrib[of "a/(a+b)" "b/(a+b)" y] assms add_divide_distrib[of a b "a+b"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7296	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7297	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7298	finally have "z = y - e *\<^sub>R (y-x)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7299	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7300	moreover have "e > 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7301	using e_def assms divide_pos_pos[of a "a+b"] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7302	moreover have "e \<le> 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7303	using e_def assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7304	ultimately show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7305	using that[of e] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7306	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7307
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7308	lemma convex_rel_interior_closure:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7309	fixes S :: "'n::euclidean_space set"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7310	assumes "convex S"
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7311	shows "rel_interior (closure S) = rel_interior S"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7312	proof (cases "S = {}")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7313	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7314	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7315	using assms rel_interior_convex_nonempty by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7316	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7317	case False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7318	have "rel_interior (closure S) \<supseteq> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7319	using subset_rel_interior[of S "closure S"] closure_same_affine_hull closure_subset
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7320	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7321	moreover
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7322	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7323	fix z
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7324	assume z: "z \<in> rel_interior (closure S)"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7325	obtain x where x: "x \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7326	using `S \<noteq> {}` assms rel_interior_convex_nonempty by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7327	have "z \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7328	proof (cases "x = z")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7329	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7330	then show ?thesis using x by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7331	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7332	case False
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7333	obtain e where e: "e > 0" "cball z e \<inter> affine hull closure S \<le> closure S"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7334	using z rel_interior_cball[of "closure S"] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7335	then have *: "0 < e/norm(z-x)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7336	using e False divide_pos_pos[of e "norm(z-x)"] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7337	def y \<equiv> "z + (e/norm(z-x)) *\<^sub>R (z-x)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7338	have yball: "y \<in> cball z e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7339	using mem_cball y_def dist_norm[of z y] e by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7340	have "x \<in> affine hull closure S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7341	using x rel_interior_subset_closure hull_inc[of x "closure S"] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7342	moreover have "z \<in> affine hull closure S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7343	using z rel_interior_subset hull_subset[of "closure S"] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7344	ultimately have "y \<in> affine hull closure S"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7345	using y_def affine_affine_hull[of "closure S"]
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7346	mem_affine_3_minus [of "affine hull closure S" z z x "e/norm(z-x)"] by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7347	then have "y \<in> closure S" using e yball by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7348	have "(1 + (e/norm(z-x))) \<^sub>R z = (e/norm(z-x)) \<^sub>R x + y"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7349	using y_def by (simp add: algebra_simps)
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7350	then obtain e1 where "0 < e1" "e1 \<le> 1" "z = y - e1 *\<^sub>R (y - x)"
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7351	using * convex_rel_interior_closure_aux[of "e / norm (z - x)" 1 z x y]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7352	by (auto simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7353	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7354	using rel_interior_closure_convex_shrink assms x `y \<in> closure S`
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7355	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7356	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7357	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7358	ultimately show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7359	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7360
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7361	lemma convex_interior_closure:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7362	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7363	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7364	shows "interior (closure S) = interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7365	using closure_aff_dim[of S] interior_rel_interior_gen[of S]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7366	interior_rel_interior_gen[of "closure S"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7367	convex_rel_interior_closure[of S] assms
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7368	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7369
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7370	lemma closure_eq_rel_interior_eq:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7371	fixes S1 S2 :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7372	assumes "convex S1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7373	and "convex S2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7374	shows "closure S1 = closure S2 \<longleftrightarrow> rel_interior S1 = rel_interior S2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7375	by (metis convex_rel_interior_closure convex_closure_rel_interior assms)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7376
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7377	lemma closure_eq_between:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7378	fixes S1 S2 :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7379	assumes "convex S1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7380	and "convex S2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7381	shows "closure S1 = closure S2 \<longleftrightarrow> rel_interior S1 \<le> S2 \<and> S2 \<subseteq> closure S1"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7382	(is "?A \<longleftrightarrow> ?B")
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7383	proof
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7384	assume ?A
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7385	then show ?B
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7386	by (metis assms closure_subset convex_rel_interior_closure rel_interior_subset)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7387	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7388	assume ?B
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7389	then have "closure S1 \<subseteq> closure S2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7390	by (metis assms(1) convex_closure_rel_interior closure_mono)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7391	moreover from `?B` have "closure S1 \<supseteq> closure S2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7392	by (metis closed_closure closure_minimal)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7393	ultimately show ?A ..
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7394	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7395
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7396	lemma open_inter_closure_rel_interior:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7397	fixes S A :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7398	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7399	and "open A"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7400	shows "A \<inter> closure S = {} \<longleftrightarrow> A \<inter> rel_interior S = {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7401	by (metis assms convex_closure_rel_interior open_inter_closure_eq_empty)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7402
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7403	definition "rel_frontier S = closure S - rel_interior S"
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7404
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7405	lemma closed_affine_hull:
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7406	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7407	shows "closed (affine hull S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7408	by (metis affine_affine_hull affine_closed)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7409
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7410	lemma closed_rel_frontier:
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7411	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7412	shows "closed (rel_frontier S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7413	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7414	have *: "closedin (subtopology euclidean (affine hull S)) (closure S - rel_interior S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7415	apply (rule closedin_diff[of "subtopology euclidean (affine hull S)""closure S" "rel_interior S"])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7416	using closed_closedin_trans[of "affine hull S" "closure S"] closed_affine_hull[of S]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7417	closure_affine_hull[of S] opein_rel_interior[of S]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7418	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7419	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7420	show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7421	apply (rule closedin_closed_trans[of "affine hull S" "rel_frontier S"])
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7422	unfolding rel_frontier_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7423	using * closed_affine_hull
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7424	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7425	done
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7426	qed
8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7427
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7428
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7429	lemma convex_rel_frontier_aff_dim:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7430	fixes S1 S2 :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7431	assumes "convex S1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7432	and "convex S2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7433	and "S2 \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7434	and "S1 \<le> rel_frontier S2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7435	shows "aff_dim S1 < aff_dim S2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7436	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7437	have "S1 \<subseteq> closure S2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7438	using assms unfolding rel_frontier_def by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7439	then have *: "affine hull S1 \<subseteq> affine hull S2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7440	using hull_mono[of "S1" "closure S2"] closure_same_affine_hull[of S2]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7441	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7442	then have "aff_dim S1 \<le> aff_dim S2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7443	using * aff_dim_affine_hull[of S1] aff_dim_affine_hull[of S2]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7444	aff_dim_subset[of "affine hull S1" "affine hull S2"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7445	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7446	moreover
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7447	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7448	assume eq: "aff_dim S1 = aff_dim S2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7449	then have "S1 \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7450	using aff_dim_empty[of S1] aff_dim_empty[of S2] `S2 \<noteq> {}` by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7451	have **: "affine hull S1 = affine hull S2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7452	apply (rule affine_dim_equal)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7453	using * affine_affine_hull
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7454	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7455	using `S1 \<noteq> {}` hull_subset[of S1]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7456	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7457	using eq aff_dim_affine_hull[of S1] aff_dim_affine_hull[of S2]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7458	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7459	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7460	obtain a where a: "a \<in> rel_interior S1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7461	using `S1 \<noteq> {}` rel_interior_convex_nonempty assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7462	obtain T where T: "open T" "a \<in> T \<inter> S1" "T \<inter> affine hull S1 \<subseteq> S1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7463	using mem_rel_interior[of a S1] a by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7464	then have "a \<in> T \<inter> closure S2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7465	using a assms unfolding rel_frontier_def by auto
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7466	then obtain b where b: "b \<in> T \<inter> rel_interior S2"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7467	using open_inter_closure_rel_interior[of S2 T] assms T by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7468	then have "b \<in> affine hull S1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7469	using rel_interior_subset hull_subset[of S2] ** by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7470	then have "b \<in> S1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7471	using T b by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7472	then have False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7473	using b assms unfolding rel_frontier_def by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7474	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7475	ultimately show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7476	using less_le by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7477	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7478
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7479
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7480	lemma convex_rel_interior_if:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7481	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7482	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7483	and "z \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7484	shows "\<forall>x\<in>affine hull S. \<exists>m. m > 1 \<and> (\<forall>e. e > 1 \<and> e \<le> m \<longrightarrow> (1 - e) \<^sub>R x + e \<^sub>R z \<in> S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7485	proof -
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7486	obtain e1 where e1: "e1 > 0 \<and> cball z e1 \<inter> affine hull S \<subseteq> S"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7487	using mem_rel_interior_cball[of z S] assms by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7488	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7489	fix x
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7490	assume x: "x \<in> affine hull S"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7491	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7492	assume "x \<noteq> z"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7493	def m \<equiv> "1 + e1/norm(x-z)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7494	then have "m > 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7495	using e1 `x \<noteq> z` divide_pos_pos[of e1 "norm (x - z)"] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7496	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7497	fix e
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7498	assume e: "e > 1 \<and> e \<le> m"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7499	have "z \<in> affine hull S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7500	using assms rel_interior_subset hull_subset[of S] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7501	then have : "(1 - e)\<^sub>R x + e *\<^sub>R z \<in> affine hull S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7502	using mem_affine[of "affine hull S" x z "(1-e)" e] affine_affine_hull[of S] x
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7503	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7504	have "norm (z + e \<^sub>R x - (x + e \<^sub>R z)) = norm ((e - 1) *\<^sub>R (x - z))"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7505	by (simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7506	also have "\<dots> = (e - 1) * norm (x-z)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7507	using norm_scaleR e by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7508	also have "\<dots> \<le> (m - 1) * norm (x - z)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7509	using e mult_right_mono[of _ _ "norm(x-z)"] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7510	also have "\<dots> = (e1 / norm (x - z)) * norm (x - z)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7511	using m_def by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7512	also have "\<dots> = e1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7513	using `x \<noteq> z` e1 by simp
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7514	finally have *: "norm (z + e \<^sub>R x - (x + e *\<^sub>R z)) \<le> e1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7515	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7516	have "(1 - e)\<^sub>R x+ e \<^sub>R z \<in> cball z e1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7517	using m_def **
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7518	unfolding cball_def dist_norm
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7519	by (auto simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7520	then have "(1 - e) \<^sub>R x+ e \<^sub>R z \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7521	using e * e1 by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7522	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7523	then have "\<exists>m. m > 1 \<and> (\<forall>e. e > 1 \<and> e \<le> m \<longrightarrow> (1 - e) \<^sub>R x + e \<^sub>R z \<in> S )"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7524	using `m> 1 ` by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7525	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7526	moreover
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7527	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7528	assume "x = z"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7529	def m \<equiv> "1 + e1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7530	then have "m > 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7531	using e1 by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7532	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7533	fix e
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7534	assume e: "e > 1 \<and> e \<le> m"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7535	then have "(1 - e) \<^sub>R x + e \<^sub>R z \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7536	using e1 x `x = z` by (auto simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7537	then have "(1 - e) \<^sub>R x + e \<^sub>R z \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7538	using e by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7539	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7540	then have "\<exists>m. m > 1 \<and> (\<forall>e. e > 1 \<and> e \<le> m \<longrightarrow> (1 - e) \<^sub>R x + e \<^sub>R z \<in> S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7541	using `m > 1` by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7542	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7543	ultimately have "\<exists>m. m > 1 \<and> (\<forall>e. e > 1 \<and> e \<le> m \<longrightarrow> (1 - e) \<^sub>R x + e \<^sub>R z \<in> S )"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7544	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7545	}
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7546	then show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7547	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7548
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7549	lemma convex_rel_interior_if2:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7550	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7551	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7552	assumes "z \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7553	shows "\<forall>x\<in>affine hull S. \<exists>e. e > 1 \<and> (1 - e)\<^sub>R x + e \<^sub>R z \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7554	using convex_rel_interior_if[of S z] assms by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7555
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7556	lemma convex_rel_interior_only_if:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7557	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7558	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7559	and "S \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7560	assumes "\<forall>x\<in>S. \<exists>e. e > 1 \<and> (1 - e) \<^sub>R x + e \<^sub>R z \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7561	shows "z \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7562	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7563	obtain x where x: "x \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7564	using rel_interior_convex_nonempty assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7565	then have "x \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7566	using rel_interior_subset by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7567	then obtain e where e: "e > 1 \<and> (1 - e) \<^sub>R x + e \<^sub>R z \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7568	using assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7569	def y \<equiv> "(1 - e) \<^sub>R x + e \<^sub>R z"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7570	then have "y \<in> S" using e by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7571	def e1 \<equiv> "1/e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7572	then have "0 < e1 \<and> e1 < 1" using e by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7573	then have "z =y - (1 - e1) *\<^sub>R (y - x)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7574	using e1_def y_def by (auto simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7575	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7576	using rel_interior_convex_shrink[of S x y "1-e1"] `0 < e1 \<and> e1 < 1` `y \<in> S` x assms
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7577	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7578	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7579
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7580	lemma convex_rel_interior_iff:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7581	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7582	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7583	and "S \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7584	shows "z \<in> rel_interior S \<longleftrightarrow> (\<forall>x\<in>S. \<exists>e. e > 1 \<and> (1 - e) \<^sub>R x + e \<^sub>R z \<in> S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7585	using assms hull_subset[of S "affine"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7586	convex_rel_interior_if[of S z] convex_rel_interior_only_if[of S z]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7587	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7588
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7589	lemma convex_rel_interior_iff2:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7590	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7591	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7592	and "S \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7593	shows "z \<in> rel_interior S \<longleftrightarrow> (\<forall>x\<in>affine hull S. \<exists>e. e > 1 \<and> (1 - e) \<^sub>R x + e \<^sub>R z \<in> S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7594	using assms hull_subset[of S] convex_rel_interior_if2[of S z] convex_rel_interior_only_if[of S z]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7595	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7596
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7597	lemma convex_interior_iff:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7598	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7599	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7600	shows "z \<in> interior S \<longleftrightarrow> (\<forall>x. \<exists>e. e > 0 \<and> z + e *\<^sub>R x \<in> S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7601	proof (cases "aff_dim S = int DIM('n)")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7602	case False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7603	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7604	assume "z \<in> interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7605	then have False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7606	using False interior_rel_interior_gen[of S] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7607	}
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7608	moreover
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7609	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7610	assume r: "\<forall>x. \<exists>e. e > 0 \<and> z + e *\<^sub>R x \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7611	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7612	fix x
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7613	obtain e1 where e1: "e1 > 0 \<and> z + e1 *\<^sub>R (x - z) \<in> S"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7614	using r by auto
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7615	obtain e2 where e2: "e2 > 0 \<and> z + e2 *\<^sub>R (z - x) \<in> S"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7616	using r by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7617	def x1 \<equiv> "z + e1 *\<^sub>R (x - z)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7618	then have x1: "x1 \<in> affine hull S"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7619	using e1 hull_subset[of S] by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7620	def x2 \<equiv> "z + e2 *\<^sub>R (z - x)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7621	then have x2: "x2 \<in> affine hull S"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7622	using e2 hull_subset[of S] by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7623	have *: "e1/(e1+e2) + e2/(e1+e2) = 1"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7624	using add_divide_distrib[of e1 e2 "e1+e2"] e1 e2 by simp
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7625	then have "z = (e2/(e1+e2)) \<^sub>R x1 + (e1/(e1+e2)) \<^sub>R x2"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7626	using x1_def x2_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7627	apply (auto simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7628	using scaleR_left_distrib[of "e1/(e1+e2)" "e2/(e1+e2)" z]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7629	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7630	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7631	then have z: "z \<in> affine hull S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7632	using mem_affine[of "affine hull S" x1 x2 "e2/(e1+e2)" "e1/(e1+e2)"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7633	x1 x2 affine_affine_hull[of S] *
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7634	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7635	have "x1 - x2 = (e1 + e2) *\<^sub>R (x - z)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7636	using x1_def x2_def by (auto simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7637	then have "x = z+(1/(e1+e2)) *\<^sub>R (x1-x2)"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7638	using e1 e2 by simp
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7639	then have "x \<in> affine hull S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7640	using mem_affine_3_minus[of "affine hull S" z x1 x2 "1/(e1+e2)"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7641	x1 x2 z affine_affine_hull[of S]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7642	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7643	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7644	then have "affine hull S = UNIV"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7645	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7646	then have "aff_dim S = int DIM('n)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7647	using aff_dim_affine_hull[of S] by (simp add: aff_dim_univ)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7648	then have False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7649	using False by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7650	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7651	ultimately show ?thesis by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7652	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7653	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7654	then have "S \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7655	using aff_dim_empty[of S] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7656	have *: "affine hull S = UNIV"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7657	using True affine_hull_univ by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7658	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7659	assume "z \<in> interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7660	then have "z \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7661	using True interior_rel_interior_gen[of S] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7662	then have *: "\<forall>x. \<exists>e. e > 1 \<and> (1 - e) \<^sub>R x + e *\<^sub>R z \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7663	using convex_rel_interior_iff2[of S z] assms `S \<noteq> {}` * by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7664	fix x
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7665	obtain e1 where e1: "e1 > 1" "(1 - e1) \<^sub>R (z - x) + e1 \<^sub>R z \<in> S"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7666	using **[rule_format, of "z-x"] by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7667	def e \<equiv> "e1 - 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7668	then have "(1 - e1) \<^sub>R (z - x) + e1 \<^sub>R z = z + e *\<^sub>R x"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7669	by (simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7670	then have "e > 0" "z + e *\<^sub>R x \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7671	using e1 e_def by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7672	then have "\<exists>e. e > 0 \<and> z + e *\<^sub>R x \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7673	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7674	}
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7675	moreover
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7676	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7677	assume r: "\<forall>x. \<exists>e. e > 0 \<and> z + e *\<^sub>R x \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7678	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7679	fix x
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7680	obtain e1 where e1: "e1 > 0" "z + e1 *\<^sub>R (z - x) \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7681	using r[rule_format, of "z-x"] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7682	def e \<equiv> "e1 + 1"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7683	then have "z + e1 \<^sub>R (z - x) = (1 - e) \<^sub>R x + e *\<^sub>R z"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7684	by (simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7685	then have "e > 1" "(1 - e)\<^sub>R x + e \<^sub>R z \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7686	using e1 e_def by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7687	then have "\<exists>e. e > 1 \<and> (1 - e) \<^sub>R x + e \<^sub>R z \<in> S" by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7688	}
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7689	then have "z \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7690	using convex_rel_interior_iff2[of S z] assms `S \<noteq> {}` by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7691	then have "z \<in> interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7692	using True interior_rel_interior_gen[of S] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7693	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7694	ultimately show ?thesis by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7695	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7696
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7697
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	7698	subsubsection {* Relative interior and closure under common operations *}
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7699
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7700	lemma rel_interior_inter_aux: "\<Inter>{rel_interior S \|S. S : I} \<subseteq> \<Inter>I"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7701	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7702	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7703	fix y
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7704	assume "y \<in> \<Inter>{rel_interior S \|S. S : I}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7705	then have y: "\<forall>S \<in> I. y \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7706	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7707	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7708	fix S
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7709	assume "S \<in> I"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7710	then have "y \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7711	using rel_interior_subset y by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7712	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7713	then have "y \<in> \<Inter>I" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7714	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7715	then show ?thesis by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7716	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7717
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7718	lemma closure_inter: "closure (\<Inter>I) \<le> \<Inter>{closure S \|S. S \<in> I}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7719	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7720	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7721	fix y
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7722	assume "y \<in> \<Inter>I"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7723	then have y: "\<forall>S \<in> I. y \<in> S" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7724	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7725	fix S
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7726	assume "S \<in> I"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7727	then have "y \<in> closure S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7728	using closure_subset y by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7729	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7730	then have "y \<in> \<Inter>{closure S \|S. S \<in> I}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7731	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7732	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7733	then have "\<Inter>I \<subseteq> \<Inter>{closure S \|S. S \<in> I}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7734	by auto
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7735	moreover have "closed (\<Inter>{closure S \|S. S \<in> I})"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7736	unfolding closed_Inter closed_closure by auto
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7737	ultimately show ?thesis using closure_hull[of "\<Inter>I"]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7738	hull_minimal[of "\<Inter>I" "\<Inter>{closure S \|S. S \<in> I}" "closed"] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7739	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7740
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7741	lemma convex_closure_rel_interior_inter:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7742	assumes "\<forall>S\<in>I. convex (S :: 'n::euclidean_space set)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7743	and "\<Inter>{rel_interior S \|S. S \<in> I} \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7744	shows "\<Inter>{closure S \|S. S \<in> I} \<le> closure (\<Inter>{rel_interior S \|S. S \<in> I})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7745	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7746	obtain x where x: "\<forall>S\<in>I. x \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7747	using assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7748	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7749	fix y
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7750	assume "y \<in> \<Inter>{closure S \|S. S \<in> I}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7751	then have y: "\<forall>S \<in> I. y \<in> closure S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7752	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7753	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7754	assume "y = x"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7755	then have "y \<in> closure (\<Inter>{rel_interior S \|S. S \<in> I})"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7756	using x closure_subset[of "\<Inter>{rel_interior S \|S. S \<in> I}"] by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7757	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7758	moreover
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7759	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7760	assume "y \<noteq> x"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7761	{ fix e :: real
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7762	assume e: "e > 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7763	def e1 \<equiv> "min 1 (e/norm (y - x))"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7764	then have e1: "e1 > 0" "e1 \<le> 1" "e1 * norm (y - x) \<le> e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7765	using `y \<noteq> x` `e > 0` divide_pos_pos[of e] le_divide_eq[of e1 e "norm (y - x)"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7766	by simp_all
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7767	def z \<equiv> "y - e1 *\<^sub>R (y - x)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7768	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7769	fix S
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7770	assume "S \<in> I"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7771	then have "z \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7772	using rel_interior_closure_convex_shrink[of S x y e1] assms x y e1 z_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7773	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7774	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7775	then have *: "z \<in> \<Inter>{rel_interior S \|S. S \<in> I}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7776	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7777	have "\<exists>z. z \<in> \<Inter>{rel_interior S \|S. S \<in> I} \<and> z \<noteq> y \<and> dist z y \<le> e"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7778	apply (rule_tac x="z" in exI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7779	using `y \<noteq> x` z_def * e1 e dist_norm[of z y]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7780	apply simp
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7781	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7782	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7783	then have "y islimpt \<Inter>{rel_interior S \|S. S \<in> I}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7784	unfolding islimpt_approachable_le by blast
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7785	then have "y \<in> closure (\<Inter>{rel_interior S \|S. S \<in> I})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7786	unfolding closure_def by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7787	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7788	ultimately have "y \<in> closure (\<Inter>{rel_interior S \|S. S \<in> I})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7789	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7790	}
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7791	then show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7792	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7793
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7794
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7795	lemma convex_closure_inter:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7796	assumes "\<forall>S\<in>I. convex (S :: 'n::euclidean_space set)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7797	and "\<Inter>{rel_interior S \|S. S \<in> I} \<noteq> {}"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7798	shows "closure (\<Inter>I) = \<Inter>{closure S \|S. S \<in> I}"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7799	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7800	have "\<Inter>{closure S \|S. S \<in> I} \<le> closure (\<Inter>{rel_interior S \|S. S \<in> I})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7801	using convex_closure_rel_interior_inter assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7802	moreover
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7803	have "closure (\<Inter>{rel_interior S \|S. S \<in> I}) \<le> closure (\<Inter> I)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7804	using rel_interior_inter_aux closure_mono[of "\<Inter>{rel_interior S \|S. S \<in> I}" "\<Inter>I"]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7805	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7806	ultimately show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7807	using closure_inter[of I] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7808	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7809
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7810	lemma convex_inter_rel_interior_same_closure:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7811	assumes "\<forall>S\<in>I. convex (S :: 'n::euclidean_space set)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7812	and "\<Inter>{rel_interior S \|S. S \<in> I} \<noteq> {}"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7813	shows "closure (\<Inter>{rel_interior S \|S. S \<in> I}) = closure (\<Inter>I)"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7814	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7815	have "\<Inter>{closure S \|S. S \<in> I} \<le> closure (\<Inter>{rel_interior S \|S. S \<in> I})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7816	using convex_closure_rel_interior_inter assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7817	moreover
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7818	have "closure (\<Inter>{rel_interior S \|S. S \<in> I}) \<le> closure (\<Inter>I)"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7819	using rel_interior_inter_aux closure_mono[of "\<Inter>{rel_interior S \|S. S \<in> I}" "\<Inter>I"]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7820	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7821	ultimately show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7822	using closure_inter[of I] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7823	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7824
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7825	lemma convex_rel_interior_inter:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7826	assumes "\<forall>S\<in>I. convex (S :: 'n::euclidean_space set)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7827	and "\<Inter>{rel_interior S \|S. S \<in> I} \<noteq> {}"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7828	shows "rel_interior (\<Inter>I) \<subseteq> \<Inter>{rel_interior S \|S. S \<in> I}"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7829	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7830	have "convex (\<Inter>I)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7831	using assms convex_Inter by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7832	moreover
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	7833	have "convex (\<Inter>{rel_interior S \|S. S \<in> I})"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7834	apply (rule convex_Inter)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7835	using assms convex_rel_interior
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7836	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7837	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7838	ultimately
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7839	have "rel_interior (\<Inter>{rel_interior S \|S. S \<in> I}) = rel_interior (\<Inter>I)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7840	using convex_inter_rel_interior_same_closure assms
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7841	closure_eq_rel_interior_eq[of "\<Inter>{rel_interior S \|S. S \<in> I}" "\<Inter>I"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7842	by blast
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7843	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7844	using rel_interior_subset[of "\<Inter>{rel_interior S \|S. S \<in> I}"] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7845	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7846
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7847	lemma convex_rel_interior_finite_inter:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7848	assumes "\<forall>S\<in>I. convex (S :: 'n::euclidean_space set)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7849	and "\<Inter>{rel_interior S \|S. S \<in> I} \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7850	and "finite I"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7851	shows "rel_interior (\<Inter>I) = \<Inter>{rel_interior S \|S. S \<in> I}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7852	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7853	have "\<Inter>I \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7854	using assms rel_interior_inter_aux[of I] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7855	have "convex (\<Inter>I)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7856	using convex_Inter assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7857	show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7858	proof (cases "I = {}")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7859	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7860	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7861	using Inter_empty rel_interior_univ2 by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7862	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7863	case False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7864	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7865	fix z
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7866	assume z: "z \<in> \<Inter>{rel_interior S \|S. S \<in> I}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7867	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7868	fix x
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7869	assume x: "x \<in> Inter I"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7870	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7871	fix S
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7872	assume S: "S \<in> I"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7873	then have "z \<in> rel_interior S" "x \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7874	using z x by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7875	then have "\<exists>m. m > 1 \<and> (\<forall>e. e > 1 \<and> e \<le> m \<longrightarrow> (1 - e)\<^sub>R x + e \<^sub>R z \<in> S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7876	using convex_rel_interior_if[of S z] S assms hull_subset[of S] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7877	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7878	then obtain mS where
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7879	mS: "\<forall>S\<in>I. mS S > 1 \<and> (\<forall>e. e > 1 \<and> e \<le> mS S \<longrightarrow> (1 - e) \<^sub>R x + e \<^sub>R z \<in> S)" by metis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7880	def e \<equiv> "Min (mS ` I)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7881	then have "e \<in> mS ` I" using assms `I \<noteq> {}` by simp
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7882	then have "e > 1" using mS by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7883	moreover have "\<forall>S\<in>I. e \<le> mS S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7884	using e_def assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7885	ultimately have "\<exists>e > 1. (1 - e) \<^sub>R x + e \<^sub>R z \<in> \<Inter>I"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7886	using mS by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7887	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7888	then have "z \<in> rel_interior (\<Inter>I)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7889	using convex_rel_interior_iff[of "\<Inter>I" z] `\<Inter>I \<noteq> {}` `convex (\<Inter>I)` by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7890	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7891	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7892	using convex_rel_interior_inter[of I] assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7893	qed
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7894	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7895
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7896	lemma convex_closure_inter_two:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7897	fixes S T :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7898	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7899	and "convex T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7900	assumes "rel_interior S \<inter> rel_interior T \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7901	shows "closure (S \<inter> T) = closure S \<inter> closure T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7902	using convex_closure_inter[of "{S,T}"] assms by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7903
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7904	lemma convex_rel_interior_inter_two:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7905	fixes S T :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7906	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7907	and "convex T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7908	and "rel_interior S \<inter> rel_interior T \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7909	shows "rel_interior (S \<inter> T) = rel_interior S \<inter> rel_interior T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7910	using convex_rel_interior_finite_inter[of "{S,T}"] assms by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7911
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7912	lemma convex_affine_closure_inter:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7913	fixes S T :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7914	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7915	and "affine T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7916	and "rel_interior S \<inter> T \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7917	shows "closure (S \<inter> T) = closure S \<inter> T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7918	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7919	have "affine hull T = T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7920	using assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7921	then have "rel_interior T = T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7922	using rel_interior_univ[of T] by metis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7923	moreover have "closure T = T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7924	using assms affine_closed[of T] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7925	ultimately show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7926	using convex_closure_inter_two[of S T] assms affine_imp_convex by auto
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7927	qed
8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7928
8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	7929	lemma convex_affine_rel_interior_inter:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7930	fixes S T :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7931	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7932	and "affine T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7933	and "rel_interior S \<inter> T \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7934	shows "rel_interior (S \<inter> T) = rel_interior S \<inter> T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7935	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7936	have "affine hull T = T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7937	using assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7938	then have "rel_interior T = T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7939	using rel_interior_univ[of T] by metis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7940	moreover have "closure T = T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7941	using assms affine_closed[of T] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7942	ultimately show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7943	using convex_rel_interior_inter_two[of S T] assms affine_imp_convex by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7944	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7945
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7946	lemma subset_rel_interior_convex:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7947	fixes S T :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7948	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7949	and "convex T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7950	and "S \<le> closure T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7951	and "\<not> S \<subseteq> rel_frontier T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7952	shows "rel_interior S \<subseteq> rel_interior T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7953	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7954	have *: "S \<inter> closure T = S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7955	using assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7956	have "\<not> rel_interior S \<subseteq> rel_frontier T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7957	using closure_mono[of "rel_interior S" "rel_frontier T"] closed_rel_frontier[of T]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7958	closure_closed[of S] convex_closure_rel_interior[of S] closure_subset[of S] assms
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7959	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7960	then have "rel_interior S \<inter> rel_interior (closure T) \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7961	using assms rel_frontier_def[of T] rel_interior_subset convex_rel_interior_closure[of T]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7962	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7963	then have "rel_interior S \<inter> rel_interior T = rel_interior (S \<inter> closure T)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7964	using assms convex_closure convex_rel_interior_inter_two[of S "closure T"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7965	convex_rel_interior_closure[of T]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7966	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7967	also have "\<dots> = rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7968	using * by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7969	finally show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7970	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7971	qed
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7972
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	7973	lemma rel_interior_convex_linear_image:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7974	fixes f :: "'m::euclidean_space \<Rightarrow> 'n::euclidean_space"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7975	assumes "linear f"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7976	and "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7977	shows "f ` (rel_interior S) = rel_interior (f ` S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7978	proof (cases "S = {}")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7979	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7980	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7981	using assms rel_interior_empty rel_interior_convex_nonempty by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7982	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7983	case False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7984	have *: "f ` (rel_interior S) \<subseteq> f ` S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7985	unfolding image_mono using rel_interior_subset by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7986	have "f ` S \<subseteq> f ` (closure S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7987	unfolding image_mono using closure_subset by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7988	also have "\<dots> = f ` (closure (rel_interior S))"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7989	using convex_closure_rel_interior assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7990	also have "\<dots> \<subseteq> closure (f ` (rel_interior S))"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7991	using closure_linear_image assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7992	finally have "closure (f ` S) = closure (f ` rel_interior S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7993	using closure_mono[of "f ` S" "closure (f ` rel_interior S)"] closure_closure
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7994	closure_mono[of "f ` rel_interior S" "f ` S"] *
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7995	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7996	then have "rel_interior (f ` S) = rel_interior (f ` rel_interior S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	7997	using assms convex_rel_interior
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	7998	linear_conv_bounded_linear[of f] convex_linear_image[of _ S]
3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	7999	convex_linear_image[of _ "rel_interior S"]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8000	closure_eq_rel_interior_eq[of "f ` S" "f ` rel_interior S"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8001	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8002	then have "rel_interior (f ` S) \<subseteq> f ` rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8003	using rel_interior_subset by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8004	moreover
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8005	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8006	fix z
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8007	assume "z \<in> f ` rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8008	then obtain z1 where z1: "z1 \<in> rel_interior S" "f z1 = z" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8009	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8010	fix x
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8011	assume "x \<in> f ` S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8012	then obtain x1 where x1: "x1 \<in> S" "f x1 = x" by auto
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8013	then obtain e where e: "e > 1" "(1 - e) \<^sub>R x1 + e \<^sub>R z1 : S"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8014	using convex_rel_interior_iff[of S z1] `convex S` x1 z1 by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8015	moreover have "f ((1 - e) \<^sub>R x1 + e \<^sub>R z1) = (1 - e) \<^sub>R x + e \<^sub>R z"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8016	using x1 z1 `linear f` by (simp add: linear_add_cmul)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8017	ultimately have "(1 - e) \<^sub>R x + e \<^sub>R z : f ` S"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8018	using imageI[of "(1 - e) \<^sub>R x1 + e \<^sub>R z1" S f] by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8019	then have "\<exists>e. e > 1 \<and> (1 - e) \<^sub>R x + e \<^sub>R z : f ` S"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8020	using e by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8021	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8022	then have "z \<in> rel_interior (f ` S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8023	using convex_rel_interior_iff[of "f ` S" z] `convex S`
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8024	`linear f` `S \<noteq> {}` convex_linear_image[of f S] linear_conv_bounded_linear[of f]
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8025	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8026	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8027	ultimately show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8028	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8029
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8030	lemma rel_interior_convex_linear_preimage:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8031	fixes f :: "'m::euclidean_space \<Rightarrow> 'n::euclidean_space"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8032	assumes "linear f"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8033	and "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8034	and "f -` (rel_interior S) \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8035	shows "rel_interior (f -` S) = f -` (rel_interior S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8036	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8037	have "S \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8038	using assms rel_interior_empty by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8039	have nonemp: "f -` S \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8040	by (metis assms(3) rel_interior_subset subset_empty vimage_mono)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8041	then have "S \<inter> (range f) \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8042	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8043	have conv: "convex (f -` S)"
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	8044	using convex_linear_vimage assms by auto
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8045	then have "convex (S \<inter> range f)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8046	by (metis assms(1) assms(2) convex_Int subspace_UNIV subspace_imp_convex subspace_linear_image)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8047	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8048	fix z
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8049	assume "z \<in> f -` (rel_interior S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8050	then have z: "f z : rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8051	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8052	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8053	fix x
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8054	assume "x \<in> f -` S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8055	then have "f x \<in> S" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8056	then obtain e where e: "e > 1" "(1 - e) \<^sub>R f x + e \<^sub>R f z \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8057	using convex_rel_interior_iff[of S "f z"] z assms `S \<noteq> {}` by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8058	moreover have "(1 - e) \<^sub>R f x + e \<^sub>R f z = f ((1 - e) \<^sub>R x + e \<^sub>R z)"
53600 8fda7ad57466 make 'linear' into a sublocale of 'bounded_linear'; huffman parents: 53406 diff changeset	8059	using `linear f` by (simp add: linear_iff)
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8060	ultimately have "\<exists>e. e > 1 \<and> (1 - e) \<^sub>R x + e \<^sub>R z \<in> f -` S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8061	using e by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8062	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8063	then have "z \<in> rel_interior (f -` S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8064	using convex_rel_interior_iff[of "f -` S" z] conv nonemp by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8065	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8066	moreover
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8067	{
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8068	fix z
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8069	assume z: "z \<in> rel_interior (f -` S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8070	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8071	fix x
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8072	assume "x \<in> S \<inter> range f"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8073	then obtain y where y: "f y = x" "y \<in> f -` S" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8074	then obtain e where e: "e > 1" "(1 - e) \<^sub>R y + e \<^sub>R z \<in> f -` S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8075	using convex_rel_interior_iff[of "f -` S" z] z conv by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8076	moreover have "(1 - e) \<^sub>R x + e \<^sub>R f z = f ((1 - e) \<^sub>R y + e \<^sub>R z)"
53600 8fda7ad57466 make 'linear' into a sublocale of 'bounded_linear'; huffman parents: 53406 diff changeset	8077	using `linear f` y by (simp add: linear_iff)
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8078	ultimately have "\<exists>e. e > 1 \<and> (1 - e) \<^sub>R x + e \<^sub>R f z \<in> S \<inter> range f"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8079	using e by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8080	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8081	then have "f z \<in> rel_interior (S \<inter> range f)"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8082	using `convex (S \<inter> (range f))` `S \<inter> range f \<noteq> {}`
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8083	convex_rel_interior_iff[of "S \<inter> (range f)" "f z"]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8084	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8085	moreover have "affine (range f)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8086	by (metis assms(1) subspace_UNIV subspace_imp_affine subspace_linear_image)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8087	ultimately have "f z \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8088	using convex_affine_rel_interior_inter[of S "range f"] assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8089	then have "z \<in> f -` (rel_interior S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8090	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8091	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8092	ultimately show ?thesis by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8093	qed
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	8094
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8095	lemma rel_interior_direct_sum:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8096	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8097	and T :: "'m::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8098	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8099	and "convex T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8100	shows "rel_interior (S \<times> T) = rel_interior S \<times> rel_interior T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8101	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8102	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8103	assume "S = {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8104	then have ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8105	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8106	using rel_interior_empty
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8107	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8108	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8109	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8110	moreover
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8111	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8112	assume "T = {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8113	then have ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8114	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8115	using rel_interior_empty
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8116	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8117	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8118	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8119	moreover
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8120	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8121	assume "S \<noteq> {}" "T \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8122	then have ri: "rel_interior S \<noteq> {}" "rel_interior T \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8123	using rel_interior_convex_nonempty assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8124	then have "fst -` rel_interior S \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8125	using fst_vimage_eq_Times[of "rel_interior S"] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8126	then have "rel_interior ((fst :: 'n * 'm \<Rightarrow> 'n) -` S) = fst -` rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8127	using fst_linear `convex S` rel_interior_convex_linear_preimage[of fst S] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8128	then have s: "rel_interior (S \<times> (UNIV :: 'm set)) = rel_interior S \<times> UNIV"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8129	by (simp add: fst_vimage_eq_Times)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8130	from ri have "snd -` rel_interior T \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8131	using snd_vimage_eq_Times[of "rel_interior T"] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8132	then have "rel_interior ((snd :: 'n * 'm \<Rightarrow> 'm) -` T) = snd -` rel_interior T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8133	using snd_linear `convex T` rel_interior_convex_linear_preimage[of snd T] by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8134	then have t: "rel_interior ((UNIV :: 'n set) \<times> T) = UNIV \<times> rel_interior T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8135	by (simp add: snd_vimage_eq_Times)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8136	from s t have *: "rel_interior (S \<times> (UNIV :: 'm set)) \<inter> rel_interior ((UNIV :: 'n set) \<times> T) =
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8137	rel_interior S \<times> rel_interior T" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8138	have "S \<times> T = S \<times> (UNIV :: 'm set) \<inter> (UNIV :: 'n set) \<times> T"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8139	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8140	then have "rel_interior (S \<times> T) = rel_interior ((S \<times> (UNIV :: 'm set)) \<inter> ((UNIV :: 'n set) \<times> T))"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8141	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8142	also have "\<dots> = rel_interior (S \<times> (UNIV :: 'm set)) \<inter> rel_interior ((UNIV :: 'n set) \<times> T)"
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8143	apply (subst convex_rel_interior_inter_two[of "S \<times> (UNIV :: 'm set)" "(UNIV :: 'n set) \<times> T"])
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	8144	using * ri assms convex_Times
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8145	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8146	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8147	finally have ?thesis using * by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8148	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8149	ultimately show ?thesis by blast
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8150	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8151
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	8152	lemma rel_interior_scaleR:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8153	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8154	assumes "c \<noteq> 0"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8155	shows "(op \<^sub>R c) ` (rel_interior S) = rel_interior ((op \<^sub>R c) ` S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8156	using rel_interior_injective_linear_image[of "(op *\<^sub>R c)" S]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8157	linear_conv_bounded_linear[of "op *\<^sub>R c"] linear_scaleR injective_scaleR[of c] assms
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8158	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8159
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	8160	lemma rel_interior_convex_scaleR:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8161	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8162	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8163	shows "(op \<^sub>R c) ` (rel_interior S) = rel_interior ((op \<^sub>R c) ` S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8164	by (metis assms linear_scaleR rel_interior_convex_linear_image)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8165
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	8166	lemma convex_rel_open_scaleR:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8167	fixes S :: "'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8168	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8169	and "rel_open S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8170	shows "convex ((op \<^sub>R c) ` S) \<and> rel_open ((op \<^sub>R c) ` S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8171	by (metis assms convex_scaling rel_interior_convex_scaleR rel_open_def)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8172
49531 8d68162b7826 tuned whitespace; wenzelm parents: 49530 diff changeset	8173	lemma convex_rel_open_finite_inter:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8174	assumes "\<forall>S\<in>I. convex (S :: 'n::euclidean_space set) \<and> rel_open S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8175	and "finite I"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8176	shows "convex (\<Inter>I) \<and> rel_open (\<Inter>I)"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8177	proof (cases "\<Inter>{rel_interior S \|S. S \<in> I} = {}")
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8178	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8179	then have "\<Inter>I = {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8180	using assms unfolding rel_open_def by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8181	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8182	unfolding rel_open_def using rel_interior_empty by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8183	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8184	case False
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8185	then have "rel_open (\<Inter>I)"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8186	using assms unfolding rel_open_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8187	using convex_rel_interior_finite_inter[of I]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8188	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8189	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8190	using convex_Inter assms by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8191	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8192
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8193	lemma convex_rel_open_linear_image:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8194	fixes f :: "'m::euclidean_space \<Rightarrow> 'n::euclidean_space"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8195	assumes "linear f"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8196	and "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8197	and "rel_open S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8198	shows "convex (f ` S) \<and> rel_open (f ` S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8199	by (metis assms convex_linear_image rel_interior_convex_linear_image
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8200	linear_conv_bounded_linear rel_open_def)
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8201
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8202	lemma convex_rel_open_linear_preimage:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8203	fixes f :: "'m::euclidean_space \<Rightarrow> 'n::euclidean_space"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8204	assumes "linear f"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8205	and "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8206	and "rel_open S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8207	shows "convex (f -` S) \<and> rel_open (f -` S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8208	proof (cases "f -` (rel_interior S) = {}")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8209	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8210	then have "f -` S = {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8211	using assms unfolding rel_open_def by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8212	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8213	unfolding rel_open_def using rel_interior_empty by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8214	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8215	case False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8216	then have "rel_open (f -` S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8217	using assms unfolding rel_open_def
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8218	using rel_interior_convex_linear_preimage[of f S]
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8219	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8220	then show ?thesis
53620 3c7f5e7926dc generalized and simplified proofs of several theorems about convex sets huffman parents: 53600 diff changeset	8221	using convex_linear_vimage assms
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8222	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8223	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8224
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8225	lemma rel_interior_projection:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8226	fixes S :: "('m::euclidean_space \<times> 'n::euclidean_space) set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8227	and f :: "'m::euclidean_space \<Rightarrow> 'n::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8228	assumes "convex S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8229	and "f = (\<lambda>y. {z. (y, z) \<in> S})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8230	shows "(y, z) \<in> rel_interior S \<longleftrightarrow> (y \<in> rel_interior {y. (f y \<noteq> {})} \<and> z \<in> rel_interior (f y))"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8231	proof -
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8232	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8233	fix y
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8234	assume "y \<in> {y. f y \<noteq> {}}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8235	then obtain z where "(y, z) \<in> S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8236	using assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8237	then have "\<exists>x. x \<in> S \<and> y = fst x"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8238	apply (rule_tac x="(y, z)" in exI)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8239	apply auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8240	done
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8241	then obtain x where "x \<in> S" "y = fst x"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8242	by blast
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8243	then have "y \<in> fst ` S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8244	unfolding image_def by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8245	}
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8246	then have "fst ` S = {y. f y \<noteq> {}}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8247	unfolding fst_def using assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8248	then have h1: "fst ` rel_interior S = rel_interior {y. f y \<noteq> {}}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8249	using rel_interior_convex_linear_image[of fst S] assms fst_linear by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8250	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8251	fix y
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8252	assume "y \<in> rel_interior {y. f y \<noteq> {}}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8253	then have "y \<in> fst ` rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8254	using h1 by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8255	then have *: "rel_interior S \<inter> fst -` {y} \<noteq> {}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8256	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8257	moreover have aff: "affine (fst -` {y})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8258	unfolding affine_alt by (simp add: algebra_simps)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8259	ultimately have **: "rel_interior (S \<inter> fst -` {y}) = rel_interior S \<inter> fst -` {y}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8260	using convex_affine_rel_interior_inter[of S "fst -` {y}"] assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8261	have conv: "convex (S \<inter> fst -` {y})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8262	using convex_Int assms aff affine_imp_convex by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8263	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8264	fix x
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8265	assume "x \<in> f y"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8266	then have "(y, x) \<in> S \<inter> (fst -` {y})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8267	using assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8268	moreover have "x = snd (y, x)" by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8269	ultimately have "x \<in> snd ` (S \<inter> fst -` {y})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8270	by blast
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8271	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8272	then have "snd ` (S \<inter> fst -` {y}) = f y"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8273	using assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8274	then have ***: "rel_interior (f y) = snd ` rel_interior (S \<inter> fst -` {y})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8275	using rel_interior_convex_linear_image[of snd "S \<inter> fst -` {y}"] snd_linear conv
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8276	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8277	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8278	fix z
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8279	assume "z \<in> rel_interior (f y)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8280	then have "z \<in> snd ` rel_interior (S \<inter> fst -` {y})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8281	using *** by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8282	moreover have "{y} = fst ` rel_interior (S \<inter> fst -` {y})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8283	using * ** rel_interior_subset by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8284	ultimately have "(y, z) \<in> rel_interior (S \<inter> fst -` {y})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8285	by force
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8286	then have "(y,z) \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8287	using ** by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8288	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8289	moreover
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8290	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8291	fix z
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8292	assume "(y, z) \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8293	then have "(y, z) \<in> rel_interior (S \<inter> fst -` {y})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8294	using ** by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8295	then have "z \<in> snd ` rel_interior (S \<inter> fst -` {y})"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8296	by (metis Range_iff snd_eq_Range)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8297	then have "z \<in> rel_interior (f y)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8298	using *** by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8299	}
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8300	ultimately have "\<And>z. (y, z) \<in> rel_interior S \<longleftrightarrow> z \<in> rel_interior (f y)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8301	by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8302	}
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8303	then have h2: "\<And>y z. y \<in> rel_interior {t. f t \<noteq> {}} \<Longrightarrow>
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8304	(y, z) \<in> rel_interior S \<longleftrightarrow> z \<in> rel_interior (f y)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8305	by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8306	{
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8307	fix y z
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8308	assume asm: "(y, z) \<in> rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8309	then have "y \<in> fst ` rel_interior S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8310	by (metis Domain_iff fst_eq_Domain)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8311	then have "y \<in> rel_interior {t. f t \<noteq> {}}"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8312	using h1 by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8313	then have "y \<in> rel_interior {t. f t \<noteq> {}}" and "(z : rel_interior (f y))"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8314	using h2 asm by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8315	}
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8316	then show ?thesis using h2 by blast
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8317	qed
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8318
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8319
44467 13e72da170fc change some subsection headings to subsubsection huffman parents: 44466 diff changeset	8320	subsubsection {* Relative interior of convex cone *}
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8321
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8322	lemma cone_rel_interior:
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8323	fixes S :: "'m::euclidean_space set"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8324	assumes "cone S"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8325	shows "cone ({0} \<union> rel_interior S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8326	proof (cases "S = {}")
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8327	case True
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8328	then show ?thesis
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8329	by (simp add: rel_interior_empty cone_0)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8330	next
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8331	case False
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8332	then have : "0 \<in> S \<and> (\<forall>c. c > 0 \<longrightarrow> op \<^sub>R c ` S = S)"
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8333	using cone_iff[of S] assms by auto
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8334	then have *: "0 \<in> ({0} \<union> rel_interior S)"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8335	and "\<forall>c. c > 0 \<longrightarrow> op *\<^sub>R c ` ({0} \<union> rel_interior S) = ({0} \<union> rel_interior S)"
53348 0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8336	by (auto simp add: rel_interior_scaleR)
0b467fc4e597 tuned proofs; wenzelm parents: 53347 diff changeset	8337	then show ?thesis
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8338	using cone_iff[of "{0} \<union> rel_interior S"] by auto
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8339	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8340
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8341	lemma rel_interior_convex_cone_aux:
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8342	fixes S :: "'m::euclidean_space set"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8343	assumes "convex S"
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8344	shows "(c, x) \<in> rel_interior (cone hull ({(1 :: real)} \<times> S)) \<longleftrightarrow>
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8345	c > 0 \<and> x \<in> ((op *\<^sub>R c) ` (rel_interior S))"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8346	proof (cases "S = {}")
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8347	case True
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8348	then show ?thesis
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8349	by (simp add: rel_interior_empty cone_hull_empty)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8350	next
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8351	case False
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8352	then obtain s where "s \<in> S" by auto
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8353	have conv: "convex ({(1 :: real)} \<times> S)"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8354	using convex_Times[of "{(1 :: real)}" S] assms convex_singleton[of "1 :: real"]
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8355	by auto
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8356	def f \<equiv> "\<lambda>y. {z. (y, z) \<in> cone hull ({1 :: real} \<times> S)}"
41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8357	then have *: "(c, x) \<in> rel_interior (cone hull ({(1 :: real)} \<times> S)) =
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8358	(c \<in> rel_interior {y. f y \<noteq> {}} \<and> x \<in> rel_interior (f c))"
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8359	apply (subst rel_interior_projection[of "cone hull ({(1 :: real)} \<times> S)" f c x])
41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8360	using convex_cone_hull[of "{(1 :: real)} \<times> S"] conv
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8361	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8362	done
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8363	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8364	fix y :: real
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8365	assume "y \<ge> 0"
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8366	then have "y *\<^sub>R (1,s) \<in> cone hull ({1 :: real} \<times> S)"
41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8367	using cone_hull_expl[of "{(1 :: real)} \<times> S"] `s \<in> S` by auto
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8368	then have "f y \<noteq> {}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8369	using f_def by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8370	}
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8371	then have "{y. f y \<noteq> {}} = {0..}"
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8372	using f_def cone_hull_expl[of "{1 :: real} \<times> S"] by auto
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8373	then have **: "rel_interior {y. f y \<noteq> {}} = {0<..}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8374	using rel_interior_real_semiline by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8375	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8376	fix c :: real
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8377	assume "c > 0"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8378	then have "f c = (op *\<^sub>R c ` S)"
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8379	using f_def cone_hull_expl[of "{1 :: real} \<times> S"] by auto
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8380	then have "rel_interior (f c) = op *\<^sub>R c ` rel_interior S"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8381	using rel_interior_convex_scaleR[of S c] assms by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8382	}
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8383	then show ?thesis using * ** by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8384	qed
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8385
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8386	lemma rel_interior_convex_cone:
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8387	fixes S :: "'m::euclidean_space set"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8388	assumes "convex S"
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8389	shows "rel_interior (cone hull ({1 :: real} \<times> S)) =
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8390	{(c, c *\<^sub>R x) \| c x. c > 0 \<and> x \<in> rel_interior S}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8391	(is "?lhs = ?rhs")
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8392	proof -
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8393	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8394	fix z
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8395	assume "z \<in> ?lhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8396	have *: "z = (fst z, snd z)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8397	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8398	have "z \<in> ?rhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8399	using rel_interior_convex_cone_aux[of S "fst z" "snd z"] assms `z \<in> ?lhs`
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8400	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8401	apply (rule_tac x = "fst z" in exI)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8402	apply (rule_tac x = x in exI)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8403	using *
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8404	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8405	done
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8406	}
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8407	moreover
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8408	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8409	fix z
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8410	assume "z \<in> ?rhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8411	then have "z \<in> ?lhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8412	using rel_interior_convex_cone_aux[of S "fst z" "snd z"] assms
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8413	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8414	}
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8415	ultimately show ?thesis by blast
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8416	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8417
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8418	lemma convex_hull_finite_union:
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8419	assumes "finite I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8420	assumes "\<forall>i\<in>I. convex (S i) \<and> (S i) \<noteq> {}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8421	shows "convex hull (\<Union>(S ` I)) =
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8422	{setsum (\<lambda>i. c i *\<^sub>R s i) I \| c s. (\<forall>i\<in>I. c i \<ge> 0) \<and> setsum c I = 1 \<and> (\<forall>i\<in>I. s i \<in> S i)}"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8423	(is "?lhs = ?rhs")
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8424	proof -
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8425	have "?lhs \<supseteq> ?rhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8426	proof
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8427	fix x
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8428	assume "x : ?rhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8429	then obtain c s where : "setsum (\<lambda>i. c i \<^sub>R s i) I = x" "setsum c I = 1"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8430	"(\<forall>i\<in>I. c i \<ge> 0) \<and> (\<forall>i\<in>I. s i \<in> S i)" by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8431	then have "\<forall>i\<in>I. s i \<in> convex hull (\<Union>(S ` I))"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8432	using hull_subset[of "\<Union>(S ` I)" convex] by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8433	then show "x \<in> ?lhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8434	unfolding *(1)[symmetric]
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8435	apply (subst convex_setsum[of I "convex hull \<Union>(S ` I)" c s])
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8436	using * assms convex_convex_hull
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8437	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8438	done
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8439	qed
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8440
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8441	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8442	fix i
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8443	assume "i \<in> I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8444	with assms have "\<exists>p. p \<in> S i" by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8445	}
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8446	then obtain p where p: "\<forall>i\<in>I. p i \<in> S i" by metis
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8447
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8448	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8449	fix i
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8450	assume "i \<in> I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8451	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8452	fix x
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8453	assume "x \<in> S i"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8454	def c \<equiv> "\<lambda>j. if j = i then 1::real else 0"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8455	then have *: "setsum c I = 1"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8456	using `finite I` `i \<in> I` setsum_delta[of I i "\<lambda>j::'a. 1::real"]
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8457	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8458	def s \<equiv> "\<lambda>j. if j = i then x else p j"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8459	then have "\<forall>j. c j *\<^sub>R s j = (if j = i then x else 0)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8460	using c_def by (auto simp add: algebra_simps)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8461	then have "x = setsum (\<lambda>i. c i *\<^sub>R s i) I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8462	using s_def c_def `finite I` `i \<in> I` setsum_delta[of I i "\<lambda>j::'a. x"]
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8463	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8464	then have "x \<in> ?rhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8465	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8466	apply (rule_tac x = c in exI)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8467	apply (rule_tac x = s in exI)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8468	using * c_def s_def p `x \<in> S i`
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8469	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8470	done
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8471	}
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8472	then have "?rhs \<supseteq> S i" by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8473	}
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8474	then have *: "?rhs \<supseteq> \<Union>(S ` I)" by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8475
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8476	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8477	fix u v :: real
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8478	assume uv: "u \<ge> 0 \<and> v \<ge> 0 \<and> u + v = 1"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8479	fix x y
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8480	assume xy: "x \<in> ?rhs \<and> y \<in> ?rhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8481	from xy obtain c s where
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8482	xc: "x = setsum (\<lambda>i. c i *\<^sub>R s i) I \<and> (\<forall>i\<in>I. c i \<ge> 0) \<and> setsum c I = 1 \<and> (\<forall>i\<in>I. s i \<in> S i)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8483	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8484	from xy obtain d t where
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8485	yc: "y = setsum (\<lambda>i. d i *\<^sub>R t i) I \<and> (\<forall>i\<in>I. d i \<ge> 0) \<and> setsum d I = 1 \<and> (\<forall>i\<in>I. t i \<in> S i)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8486	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8487	def e \<equiv> "\<lambda>i. u * c i + v * d i"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8488	have ge0: "\<forall>i\<in>I. e i \<ge> 0"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8489	using e_def xc yc uv by (simp add: mult_nonneg_nonneg)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8490	have "setsum (\<lambda>i. u * c i) I = u * setsum c I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8491	by (simp add: setsum_right_distrib)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8492	moreover have "setsum (\<lambda>i. v * d i) I = v * setsum d I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8493	by (simp add: setsum_right_distrib)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8494	ultimately have sum1: "setsum e I = 1"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8495	using e_def xc yc uv by (simp add: setsum_addf)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8496	def q \<equiv> "\<lambda>i. if e i = 0 then p i else (u * c i / e i) \<^sub>R s i + (v d i / e i) *\<^sub>R t i"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8497	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8498	fix i
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8499	assume i: "i \<in> I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8500	have "q i \<in> S i"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8501	proof (cases "e i = 0")
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8502	case True
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8503	then show ?thesis using i p q_def by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8504	next
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8505	case False
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8506	then show ?thesis
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8507	using mem_convex_alt[of "S i" "s i" "t i" "u * (c i)" "v * (d i)"]
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8508	mult_nonneg_nonneg[of u "c i"] mult_nonneg_nonneg[of v "d i"]
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8509	assms q_def e_def i False xc yc uv
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8510	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8511	qed
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8512	}
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8513	then have qs: "\<forall>i\<in>I. q i \<in> S i" by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8514	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8515	fix i
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8516	assume i: "i \<in> I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8517	have "(u * c i) \<^sub>R s i + (v d i) \<^sub>R t i = e i \<^sub>R q i"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8518	proof (cases "e i = 0")
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8519	case True
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8520	have ge: "u * (c i) \<ge> 0 \<and> v * d i \<ge> 0"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8521	using xc yc uv i by (simp add: mult_nonneg_nonneg)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8522	moreover from ge have "u * c i \<le> 0 \<and> v * d i \<le> 0"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8523	using True e_def i by simp
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8524	ultimately have "u * c i = 0 \<and> v * d i = 0" by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8525	with True show ?thesis by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8526	next
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8527	case False
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8528	then have "(u * (c i)/(e i))\<^sub>R (s i)+(v (d i)/(e i))*\<^sub>R (t i) = q i"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8529	using q_def by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8530	then have "e i \<^sub>R ((u (c i)/(e i))\<^sub>R (s i)+(v (d i)/(e i))*\<^sub>R (t i))
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8531	= (e i) *\<^sub>R (q i)" by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8532	with False show ?thesis by (simp add: algebra_simps)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8533	qed
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8534	}
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8535	then have : "\<forall>i\<in>I. (u c i) \<^sub>R s i + (v d i) \<^sub>R t i = e i \<^sub>R q i"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8536	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8537	have "u \<^sub>R x + v \<^sub>R y = setsum (\<lambda>i. (u * c i) \<^sub>R s i + (v d i) *\<^sub>R t i) I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8538	using xc yc by (simp add: algebra_simps scaleR_right.setsum setsum_addf)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8539	also have "\<dots> = setsum (\<lambda>i. e i *\<^sub>R q i) I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8540	using * by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8541	finally have "u \<^sub>R x + v \<^sub>R y = setsum (\<lambda>i. (e i) *\<^sub>R (q i)) I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8542	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8543	then have "u \<^sub>R x + v \<^sub>R y \<in> ?rhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8544	using ge0 sum1 qs by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8545	}
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8546	then have "convex ?rhs" unfolding convex_def by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8547	then show ?thesis
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8548	using `?lhs \<supseteq> ?rhs` * hull_minimal[of "\<Union>(S ` I)" ?rhs convex]
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8549	by blast
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8550	qed
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8551
0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8552	lemma convex_hull_union_two:
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8553	fixes S T :: "'m::euclidean_space set"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8554	assumes "convex S"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8555	and "S \<noteq> {}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8556	and "convex T"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8557	and "T \<noteq> {}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8558	shows "convex hull (S \<union> T) =
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8559	{u \<^sub>R s + v \<^sub>R t \| u v s t. u \<ge> 0 \<and> v \<ge> 0 \<and> u + v = 1 \<and> s \<in> S \<and> t \<in> T}"
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8560	(is "?lhs = ?rhs")
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8561	proof
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8562	def I \<equiv> "{1::nat, 2}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8563	def s \<equiv> "\<lambda>i. if i = (1::nat) then S else T"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8564	have "\<Union>(s ` I) = S \<union> T"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8565	using s_def I_def by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8566	then have "convex hull (\<Union>(s ` I)) = convex hull (S \<union> T)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8567	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8568	moreover have "convex hull \<Union>(s ` I) =
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8569	{\<Sum> i\<in>I. c i *\<^sub>R sa i \| c sa. (\<forall>i\<in>I. 0 \<le> c i) \<and> setsum c I = 1 \<and> (\<forall>i\<in>I. sa i \<in> s i)}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8570	apply (subst convex_hull_finite_union[of I s])
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8571	using assms s_def I_def
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8572	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8573	done
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8574	moreover have
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8575	"{\<Sum>i\<in>I. c i *\<^sub>R sa i \| c sa. (\<forall>i\<in>I. 0 \<le> c i) \<and> setsum c I = 1 \<and> (\<forall>i\<in>I. sa i \<in> s i)} \<le> ?rhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8576	using s_def I_def by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8577	ultimately show "?lhs \<subseteq> ?rhs" by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8578	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8579	fix x
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8580	assume "x \<in> ?rhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8581	then obtain u v s t where : "x = u \<^sub>R s + v *\<^sub>R t \<and> u \<ge> 0 \<and> v \<ge> 0 \<and> u + v = 1 \<and> s \<in> S \<and> t \<in> T"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8582	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8583	then have "x \<in> convex hull {s, t}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8584	using convex_hull_2[of s t] by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8585	then have "x \<in> convex hull (S \<union> T)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8586	using * hull_mono[of "{s, t}" "S \<union> T"] by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8587	}
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8588	then show "?lhs \<supseteq> ?rhs" by blast
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8589	qed
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8590
40377 0e5d48096f58 Extend convex analysis by Bogdan Grechuk hoelzl parents: 39302 diff changeset	8591
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8592	subsection {* Convexity on direct sums *}
ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8593
ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8594	lemma closure_sum:
55928 2d7582309d73 generalize lemma closure_sum huffman parents: 55787 diff changeset	8595	fixes S T :: "'a::real_normed_vector set"
47445 69e96e5500df Set_Algebras: removed syntax \<oplus> and \<otimes>, in favour of plain + and * krauss parents: 47444 diff changeset	8596	shows "closure S + closure T \<subseteq> closure (S + T)"
55928 2d7582309d73 generalize lemma closure_sum huffman parents: 55787 diff changeset	8597	unfolding set_plus_image closure_Times [symmetric] split_def
2d7582309d73 generalize lemma closure_sum huffman parents: 55787 diff changeset	8598	by (intro closure_bounded_linear_image bounded_linear_add
2d7582309d73 generalize lemma closure_sum huffman parents: 55787 diff changeset	8599	bounded_linear_fst bounded_linear_snd)
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8600
ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8601	lemma rel_interior_sum:
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8602	fixes S T :: "'n::euclidean_space set"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8603	assumes "convex S"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8604	and "convex T"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8605	shows "rel_interior (S + T) = rel_interior S + rel_interior T"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8606	proof -
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8607	have "rel_interior S + rel_interior T = (\<lambda>(x,y). x + y) ` (rel_interior S \<times> rel_interior T)"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8608	by (simp add: set_plus_image)
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8609	also have "\<dots> = (\<lambda>(x,y). x + y) ` rel_interior (S \<times> T)"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8610	using rel_interior_direct_sum assms by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8611	also have "\<dots> = rel_interior (S + T)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8612	using fst_snd_linear convex_Times assms
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8613	rel_interior_convex_linear_image[of "(\<lambda>(x,y). x + y)" "S \<times> T"]
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8614	by (auto simp add: set_plus_image)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8615	finally show ?thesis ..
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8616	qed
ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8617
ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8618	lemma rel_interior_sum_gen:
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8619	fixes S :: "'a \<Rightarrow> 'n::euclidean_space set"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8620	assumes "\<forall>i\<in>I. convex (S i)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8621	shows "rel_interior (setsum S I) = setsum (\<lambda>i. rel_interior (S i)) I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8622	apply (subst setsum_set_cond_linear[of convex])
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8623	using rel_interior_sum rel_interior_sing[of "0"] assms
55929 91f245c23bc5 remove lemmas in favor of more general ones: convex(_hull)_set_{plus,setsum} huffman parents: 55928 diff changeset	8624	apply (auto simp add: convex_set_plus)
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8625	done
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8626
ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8627	lemma convex_rel_open_direct_sum:
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8628	fixes S T :: "'n::euclidean_space set"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8629	assumes "convex S"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8630	and "rel_open S"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8631	and "convex T"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8632	and "rel_open T"
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8633	shows "convex (S \<times> T) \<and> rel_open (S \<times> T)"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8634	by (metis assms convex_Times rel_interior_direct_sum rel_open_def)
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8635
ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8636	lemma convex_rel_open_sum:
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8637	fixes S T :: "'n::euclidean_space set"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8638	assumes "convex S"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8639	and "rel_open S"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8640	and "convex T"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8641	and "rel_open T"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8642	shows "convex (S + T) \<and> rel_open (S + T)"
55929 91f245c23bc5 remove lemmas in favor of more general ones: convex(_hull)_set_{plus,setsum} huffman parents: 55928 diff changeset	8643	by (metis assms convex_set_plus rel_interior_sum rel_open_def)
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8644
ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8645	lemma convex_hull_finite_union_cones:
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8646	assumes "finite I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8647	and "I \<noteq> {}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8648	assumes "\<forall>i\<in>I. convex (S i) \<and> cone (S i) \<and> S i \<noteq> {}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8649	shows "convex hull (\<Union>(S ` I)) = setsum S I"
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8650	(is "?lhs = ?rhs")
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8651	proof -
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8652	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8653	fix x
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8654	assume "x \<in> ?lhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8655	then obtain c xs where
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8656	x: "x = setsum (\<lambda>i. c i *\<^sub>R xs i) I \<and> (\<forall>i\<in>I. c i \<ge> 0) \<and> setsum c I = 1 \<and> (\<forall>i\<in>I. xs i \<in> S i)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8657	using convex_hull_finite_union[of I S] assms by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8658	def s \<equiv> "\<lambda>i. c i *\<^sub>R xs i"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8659	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8660	fix i
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8661	assume "i \<in> I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8662	then have "s i \<in> S i"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8663	using s_def x assms mem_cone[of "S i" "xs i" "c i"] by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8664	}
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8665	then have "\<forall>i\<in>I. s i \<in> S i" by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8666	moreover have "x = setsum s I" using x s_def by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8667	ultimately have "x \<in> ?rhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8668	using set_setsum_alt[of I S] assms by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8669	}
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8670	moreover
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8671	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8672	fix x
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8673	assume "x \<in> ?rhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8674	then obtain s where x: "x = setsum s I \<and> (\<forall>i\<in>I. s i \<in> S i)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8675	using set_setsum_alt[of I S] assms by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8676	def xs \<equiv> "\<lambda>i. of_nat(card I) *\<^sub>R s i"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8677	then have "x = setsum (\<lambda>i. ((1 :: real) / of_nat(card I)) *\<^sub>R xs i) I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8678	using x assms by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8679	moreover have "\<forall>i\<in>I. xs i \<in> S i"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8680	using x xs_def assms by (simp add: cone_def)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8681	moreover have "\<forall>i\<in>I. (1 :: real) / of_nat (card I) \<ge> 0"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8682	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8683	moreover have "setsum (\<lambda>i. (1 :: real) / of_nat (card I)) I = 1"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8684	using assms by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8685	ultimately have "x \<in> ?lhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8686	apply (subst convex_hull_finite_union[of I S])
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8687	using assms
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8688	apply blast
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8689	using assms
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8690	apply blast
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8691	apply rule
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8692	apply (rule_tac x = "(\<lambda>i. (1 :: real) / of_nat (card I))" in exI)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8693	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8694	done
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8695	}
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8696	ultimately show ?thesis by auto
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8697	qed
ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8698
ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8699	lemma convex_hull_union_cones_two:
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8700	fixes S T :: "'m::euclidean_space set"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8701	assumes "convex S"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8702	and "cone S"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8703	and "S \<noteq> {}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8704	assumes "convex T"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8705	and "cone T"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8706	and "T \<noteq> {}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8707	shows "convex hull (S \<union> T) = S + T"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8708	proof -
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8709	def I \<equiv> "{1::nat, 2}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8710	def A \<equiv> "(\<lambda>i. if i = (1::nat) then S else T)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8711	have "\<Union>(A ` I) = S \<union> T"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8712	using A_def I_def by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8713	then have "convex hull (\<Union>(A ` I)) = convex hull (S \<union> T)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8714	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8715	moreover have "convex hull \<Union>(A ` I) = setsum A I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8716	apply (subst convex_hull_finite_union_cones[of I A])
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8717	using assms A_def I_def
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8718	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8719	done
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8720	moreover have "setsum A I = S + T"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8721	using A_def I_def
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8722	unfolding set_plus_def
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8723	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8724	unfolding set_plus_def
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8725	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8726	done
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8727	ultimately show ?thesis by auto
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8728	qed
ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8729
ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8730	lemma rel_interior_convex_hull_union:
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8731	fixes S :: "'a \<Rightarrow> 'n::euclidean_space set"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8732	assumes "finite I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8733	and "\<forall>i\<in>I. convex (S i) \<and> S i \<noteq> {}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8734	shows "rel_interior (convex hull (\<Union>(S ` I))) =
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8735	{setsum (\<lambda>i. c i *\<^sub>R s i) I \| c s. (\<forall>i\<in>I. c i > 0) \<and> setsum c I = 1 \<and>
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8736	(\<forall>i\<in>I. s i \<in> rel_interior(S i))}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8737	(is "?lhs = ?rhs")
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8738	proof (cases "I = {}")
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8739	case True
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8740	then show ?thesis
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8741	using convex_hull_empty rel_interior_empty by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8742	next
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8743	case False
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8744	def C0 \<equiv> "convex hull (\<Union>(S ` I))"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8745	have "\<forall>i\<in>I. C0 \<ge> S i"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8746	unfolding C0_def using hull_subset[of "\<Union>(S ` I)"] by auto
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8747	def K0 \<equiv> "cone hull ({1 :: real} \<times> C0)"
41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8748	def K \<equiv> "\<lambda>i. cone hull ({1 :: real} \<times> S i)"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8749	have "\<forall>i\<in>I. K i \<noteq> {}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8750	unfolding K_def using assms
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8751	by (simp add: cone_hull_empty_iff[symmetric])
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8752	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8753	fix i
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8754	assume "i \<in> I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8755	then have "convex (K i)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8756	unfolding K_def
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8757	apply (subst convex_cone_hull)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8758	apply (subst convex_Times)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8759	using assms
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8760	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8761	done
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8762	}
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8763	then have convK: "\<forall>i\<in>I. convex (K i)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8764	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8765	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8766	fix i
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8767	assume "i \<in> I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8768	then have "K0 \<supseteq> K i"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8769	unfolding K0_def K_def
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8770	apply (subst hull_mono)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8771	using `\<forall>i\<in>I. C0 \<ge> S i`
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8772	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8773	done
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8774	}
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8775	then have "K0 \<supseteq> \<Union>(K ` I)" by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8776	moreover have "convex K0"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8777	unfolding K0_def
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8778	apply (subst convex_cone_hull)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8779	apply (subst convex_Times)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8780	unfolding C0_def
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8781	using convex_convex_hull
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8782	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8783	done
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8784	ultimately have geq: "K0 \<supseteq> convex hull (\<Union>(K ` I))"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8785	using hull_minimal[of _ "K0" "convex"] by blast
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8786	have "\<forall>i\<in>I. K i \<supseteq> {1 :: real} \<times> S i"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8787	using K_def by (simp add: hull_subset)
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8788	then have "\<Union>(K ` I) \<supseteq> {1 :: real} \<times> \<Union>(S ` I)"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8789	by auto
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8790	then have "convex hull \<Union>(K ` I) \<supseteq> convex hull ({1 :: real} \<times> \<Union>(S ` I))"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8791	by (simp add: hull_mono)
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8792	then have "convex hull \<Union>(K ` I) \<supseteq> {1 :: real} \<times> C0"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8793	unfolding C0_def
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8794	using convex_hull_Times[of "{(1 :: real)}" "\<Union>(S ` I)"] convex_hull_singleton
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8795	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8796	moreover have "cone (convex hull (\<Union>(K ` I)))"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8797	apply (subst cone_convex_hull)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8798	using cone_Union[of "K ` I"]
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8799	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8800	unfolding K_def
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8801	using cone_cone_hull
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8802	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8803	done
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8804	ultimately have "convex hull (\<Union>(K ` I)) \<supseteq> K0"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8805	unfolding K0_def
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8806	using hull_minimal[of _ "convex hull (\<Union> (K ` I))" "cone"]
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8807	by blast
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8808	then have "K0 = convex hull (\<Union>(K ` I))"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8809	using geq by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8810	also have "\<dots> = setsum K I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8811	apply (subst convex_hull_finite_union_cones[of I K])
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8812	using assms
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8813	apply blast
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8814	using False
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8815	apply blast
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8816	unfolding K_def
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8817	apply rule
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8818	apply (subst convex_cone_hull)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8819	apply (subst convex_Times)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8820	using assms cone_cone_hull `\<forall>i\<in>I. K i \<noteq> {}` K_def
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8821	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8822	done
47444 d21c95af2df7 removed "setsum_set", now subsumed by generic setsum krauss parents: 47108 diff changeset	8823	finally have "K0 = setsum K I" by auto
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8824	then have *: "rel_interior K0 = setsum (\<lambda>i. (rel_interior (K i))) I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8825	using rel_interior_sum_gen[of I K] convK by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8826	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8827	fix x
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8828	assume "x \<in> ?lhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8829	then have "(1::real, x) \<in> rel_interior K0"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8830	using K0_def C0_def rel_interior_convex_cone_aux[of C0 "1::real" x] convex_convex_hull
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8831	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8832	then obtain k where k: "(1::real, x) = setsum k I \<and> (\<forall>i\<in>I. k i \<in> rel_interior (K i))"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8833	using `finite I` * set_setsum_alt[of I "\<lambda>i. rel_interior (K i)"] by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8834	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8835	fix i
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8836	assume "i \<in> I"
55787 41a73a41f6c8 more symbols; wenzelm parents: 55697 diff changeset	8837	then have "convex (S i) \<and> k i \<in> rel_interior (cone hull {1} \<times> S i)"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8838	using k K_def assms by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8839	then have "\<exists>ci si. k i = (ci, ci *\<^sub>R si) \<and> 0 < ci \<and> si \<in> rel_interior (S i)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8840	using rel_interior_convex_cone[of "S i"] by auto
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8841	}
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8842	then obtain c s where
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8843	cs: "\<forall>i\<in>I. k i = (c i, c i *\<^sub>R s i) \<and> 0 < c i \<and> s i \<in> rel_interior (S i)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8844	by metis
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8845	then have "x = (\<Sum>i\<in>I. c i *\<^sub>R s i) \<and> setsum c I = 1"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8846	using k by (simp add: setsum_prod)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8847	then have "x \<in> ?rhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8848	using k
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8849	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8850	apply (rule_tac x = c in exI)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8851	apply (rule_tac x = s in exI)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8852	using cs
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8853	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8854	done
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8855	}
ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8856	moreover
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8857	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8858	fix x
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8859	assume "x \<in> ?rhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8860	then obtain c s where cs: "x = setsum (\<lambda>i. c i *\<^sub>R s i) I \<and>
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8861	(\<forall>i\<in>I. c i > 0) \<and> setsum c I = 1 \<and> (\<forall>i\<in>I. s i \<in> rel_interior (S i))"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8862	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8863	def k \<equiv> "\<lambda>i. (c i, c i *\<^sub>R s i)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8864	{
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8865	fix i assume "i:I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8866	then have "k i \<in> rel_interior (K i)"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8867	using k_def K_def assms cs rel_interior_convex_cone[of "S i"]
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8868	by auto
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8869	}
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8870	then have "(1::real, x) \<in> rel_interior K0"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8871	using K0_def * set_setsum_alt[of I "(\<lambda>i. rel_interior (K i))"] assms k_def cs
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8872	apply auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8873	apply (rule_tac x = k in exI)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8874	apply (simp add: setsum_prod)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8875	done
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8876	then have "x \<in> ?lhs"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8877	using K0_def C0_def rel_interior_convex_cone_aux[of C0 1 x]
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8878	by (auto simp add: convex_convex_hull)
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8879	}
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8880	ultimately show ?thesis by blast
40887 ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8881	qed
ee8d0548c148 Prove rel_interior_convex_hull_union (by Grechuck Bogdan). hoelzl parents: 40719 diff changeset	8882
50104 de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8883
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8884	lemma convex_le_Inf_differential:
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8885	fixes f :: "real \<Rightarrow> real"
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8886	assumes "convex_on I f"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8887	and "x \<in> interior I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8888	and "y \<in> I"
50104 de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8889	shows "f y \<ge> f x + Inf ((\<lambda>t. (f x - f t) / (x - t)) ` ({x<..} \<inter> I)) * (y - x)"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8890	(is "_ \<ge> _ + Inf (?F x) * (y - x)")
50104 de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8891	proof (cases rule: linorder_cases)
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8892	assume "x < y"
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8893	moreover
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8894	have "open (interior I)" by auto
55697 abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	8895	from openE[OF this `x \<in> interior I`]
abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	8896	obtain e where e: "0 < e" "ball x e \<subseteq> interior I" .
50104 de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8897	moreover def t \<equiv> "min (x + e / 2) ((x + y) / 2)"
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8898	ultimately have "x < t" "t < y" "t \<in> ball x e"
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8899	by (auto simp: dist_real_def field_simps split: split_min)
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8900	with `x \<in> interior I` e interior_subset[of I] have "t \<in> I" "x \<in> I" by auto
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8901
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8902	have "open (interior I)" by auto
55697 abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	8903	from openE[OF this `x \<in> interior I`]
abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	8904	obtain e where "0 < e" "ball x e \<subseteq> interior I" .
50104 de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8905	moreover def K \<equiv> "x - e / 2"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8906	with `0 < e` have "K \<in> ball x e" "K < x"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8907	by (auto simp: dist_real_def)
50104 de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8908	ultimately have "K \<in> I" "K < x" "x \<in> I"
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8909	using interior_subset[of I] `x \<in> interior I` by auto
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8910
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8911	have "Inf (?F x) \<le> (f x - f y) / (x - y)"
54258 adfc759263ab use bdd_above and bdd_below for conditionally complete lattices hoelzl parents: 54230 diff changeset	8912	proof (intro bdd_belowI cInf_lower2)
50104 de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8913	show "(f x - f t) / (x - t) \<in> ?F x"
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8914	using `t \<in> I` `x < t` by auto
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8915	show "(f x - f t) / (x - t) \<le> (f x - f y) / (x - y)"
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8916	using `convex_on I f` `x \<in> I` `y \<in> I` `x < t` `t < y`
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8917	by (rule convex_on_diff)
50104 de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8918	next
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8919	fix y
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8920	assume "y \<in> ?F x"
50104 de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8921	with order_trans[OF convex_on_diff[OF `convex_on I f` `K \<in> I` _ `K < x` _]]
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8922	show "(f K - f x) / (K - x) \<le> y" by auto
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8923	qed
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8924	then show ?thesis
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8925	using `x < y` by (simp add: field_simps)
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8926	next
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8927	assume "y < x"
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8928	moreover
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8929	have "open (interior I)" by auto
55697 abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	8930	from openE[OF this `x \<in> interior I`]
abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	8931	obtain e where e: "0 < e" "ball x e \<subseteq> interior I" .
50104 de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8932	moreover def t \<equiv> "x + e / 2"
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8933	ultimately have "x < t" "t \<in> ball x e"
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8934	by (auto simp: dist_real_def field_simps)
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8935	with `x \<in> interior I` e interior_subset[of I] have "t \<in> I" "x \<in> I" by auto
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8936
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8937	have "(f x - f y) / (x - y) \<le> Inf (?F x)"
51475 ebf9d4fd00ba introduct the conditional_complete_lattice type class; generalize theorems about real Sup and Inf to it hoelzl parents: 50979 diff changeset	8938	proof (rule cInf_greatest)
50104 de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8939	have "(f x - f y) / (x - y) = (f y - f x) / (y - x)"
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8940	using `y < x` by (auto simp: field_simps)
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8941	also
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8942	fix z
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8943	assume "z \<in> ?F x"
50104 de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8944	with order_trans[OF convex_on_diff[OF `convex_on I f` `y \<in> I` _ `y < x`]]
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8945	have "(f y - f x) / (y - x) \<le> z"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8946	by auto
50104 de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8947	finally show "(f x - f y) / (x - y) \<le> z" .
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8948	next
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8949	have "open (interior I)" by auto
55697 abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	8950	from openE[OF this `x \<in> interior I`]
abec82f4e3e9 tuned proofs; wenzelm parents: 54780 diff changeset	8951	obtain e where e: "0 < e" "ball x e \<subseteq> interior I" .
54465 2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8952	then have "x + e / 2 \<in> ball x e"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8953	by (auto simp: dist_real_def)
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8954	with e interior_subset[of I] have "x + e / 2 \<in> {x<..} \<inter> I"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8955	by auto
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8956	then show "?F x \<noteq> {}"
2f7867850cc3 tuned proofs; wenzelm parents: 54263 diff changeset	8957	by blast
50104 de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8958	qed
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8959	then show ?thesis
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8960	using `y < x` by (simp add: field_simps)
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8961	qed simp
de19856feb54 move theorems to be more generally useable hoelzl parents: 49962 diff changeset	8962
33175 2083bde13ce1 distinguished session for multivariate analysis himmelma parents: diff changeset	8963	end

author	huffman
	Tue, 18 Mar 2014 09:39:07 -0700
changeset 56196	32b7eafc5a52
parent 56189	c4daa97ac57a
child 56369	2704ca85be98
permissions	-rw-r--r--