isabelle: src/HOL/RealVector.thy@5691ccb8d6b5 (annotated)

haftmann@29197	1	(* Title: HOL/RealVector.thy
haftmann@27552	2	Author: Brian Huffman
huffman@20504	3	*)
huffman@20504	4
huffman@20504	5	header {* Vector Spaces and Algebras over the Reals *}
huffman@20504	6
huffman@20504	7	theory RealVector
haftmann@29197	8	imports RealPow
huffman@20504	9	begin
huffman@20504	10
huffman@20504	11	subsection {* Locale for additive functions *}
huffman@20504	12
huffman@20504	13	locale additive =
huffman@20504	14	fixes f :: "'a::ab_group_add \<Rightarrow> 'b::ab_group_add"
huffman@20504	15	assumes add: "f (x + y) = f x + f y"
huffman@27443	16	begin
huffman@20504	17
huffman@27443	18	lemma zero: "f 0 = 0"
huffman@20504	19	proof -
huffman@20504	20	have "f 0 = f (0 + 0)" by simp
huffman@20504	21	also have "\<dots> = f 0 + f 0" by (rule add)
huffman@20504	22	finally show "f 0 = 0" by simp
huffman@20504	23	qed
huffman@20504	24
huffman@27443	25	lemma minus: "f (- x) = - f x"
huffman@20504	26	proof -
huffman@20504	27	have "f (- x) + f x = f (- x + x)" by (rule add [symmetric])
huffman@20504	28	also have "\<dots> = - f x + f x" by (simp add: zero)
huffman@20504	29	finally show "f (- x) = - f x" by (rule add_right_imp_eq)
huffman@20504	30	qed
huffman@20504	31
huffman@27443	32	lemma diff: "f (x - y) = f x - f y"
huffman@20504	33	by (simp add: diff_def add minus)
huffman@20504	34
huffman@27443	35	lemma setsum: "f (setsum g A) = (\<Sum>x\<in>A. f (g x))"
huffman@22942	36	apply (cases "finite A")
huffman@22942	37	apply (induct set: finite)
huffman@22942	38	apply (simp add: zero)
huffman@22942	39	apply (simp add: add)
huffman@22942	40	apply (simp add: zero)
huffman@22942	41	done
huffman@22942	42
huffman@27443	43	end
huffman@20504	44
huffman@28029	45	subsection {* Vector spaces *}
huffman@28029	46
huffman@28029	47	locale vector_space =
huffman@28029	48	fixes scale :: "'a::field \<Rightarrow> 'b::ab_group_add \<Rightarrow> 'b"
huffman@30070	49	assumes scale_right_distrib [algebra_simps]:
huffman@30070	50	"scale a (x + y) = scale a x + scale a y"
huffman@30070	51	and scale_left_distrib [algebra_simps]:
huffman@30070	52	"scale (a + b) x = scale a x + scale b x"
huffman@28029	53	and scale_scale [simp]: "scale a (scale b x) = scale (a * b) x"
huffman@28029	54	and scale_one [simp]: "scale 1 x = x"
huffman@28029	55	begin
huffman@28029	56
huffman@28029	57	lemma scale_left_commute:
huffman@28029	58	"scale a (scale b x) = scale b (scale a x)"
huffman@28029	59	by (simp add: mult_commute)
huffman@28029	60
huffman@28029	61	lemma scale_zero_left [simp]: "scale 0 x = 0"
huffman@28029	62	and scale_minus_left [simp]: "scale (- a) x = - (scale a x)"
huffman@30070	63	and scale_left_diff_distrib [algebra_simps]:
huffman@30070	64	"scale (a - b) x = scale a x - scale b x"
huffman@28029	65	proof -
ballarin@29229	66	interpret s: additive "\<lambda>a. scale a x"
haftmann@28823	67	proof qed (rule scale_left_distrib)
huffman@28029	68	show "scale 0 x = 0" by (rule s.zero)
huffman@28029	69	show "scale (- a) x = - (scale a x)" by (rule s.minus)
huffman@28029	70	show "scale (a - b) x = scale a x - scale b x" by (rule s.diff)
huffman@28029	71	qed
huffman@28029	72
huffman@28029	73	lemma scale_zero_right [simp]: "scale a 0 = 0"
huffman@28029	74	and scale_minus_right [simp]: "scale a (- x) = - (scale a x)"
huffman@30070	75	and scale_right_diff_distrib [algebra_simps]:
huffman@30070	76	"scale a (x - y) = scale a x - scale a y"
huffman@28029	77	proof -
ballarin@29229	78	interpret s: additive "\<lambda>x. scale a x"
haftmann@28823	79	proof qed (rule scale_right_distrib)
huffman@28029	80	show "scale a 0 = 0" by (rule s.zero)
huffman@28029	81	show "scale a (- x) = - (scale a x)" by (rule s.minus)
huffman@28029	82	show "scale a (x - y) = scale a x - scale a y" by (rule s.diff)
huffman@28029	83	qed
huffman@28029	84
huffman@28029	85	lemma scale_eq_0_iff [simp]:
huffman@28029	86	"scale a x = 0 \<longleftrightarrow> a = 0 \<or> x = 0"
huffman@28029	87	proof cases
huffman@28029	88	assume "a = 0" thus ?thesis by simp
huffman@28029	89	next
huffman@28029	90	assume anz [simp]: "a \<noteq> 0"
huffman@28029	91	{ assume "scale a x = 0"
huffman@28029	92	hence "scale (inverse a) (scale a x) = 0" by simp
huffman@28029	93	hence "x = 0" by simp }
huffman@28029	94	thus ?thesis by force
huffman@28029	95	qed
huffman@28029	96
huffman@28029	97	lemma scale_left_imp_eq:
huffman@28029	98	"\<lbrakk>a \<noteq> 0; scale a x = scale a y\<rbrakk> \<Longrightarrow> x = y"
huffman@28029	99	proof -
huffman@28029	100	assume nonzero: "a \<noteq> 0"
huffman@28029	101	assume "scale a x = scale a y"
huffman@28029	102	hence "scale a (x - y) = 0"
huffman@28029	103	by (simp add: scale_right_diff_distrib)
huffman@28029	104	hence "x - y = 0" by (simp add: nonzero)
huffman@28029	105	thus "x = y" by (simp only: right_minus_eq)
huffman@28029	106	qed
huffman@28029	107
huffman@28029	108	lemma scale_right_imp_eq:
huffman@28029	109	"\<lbrakk>x \<noteq> 0; scale a x = scale b x\<rbrakk> \<Longrightarrow> a = b"
huffman@28029	110	proof -
huffman@28029	111	assume nonzero: "x \<noteq> 0"
huffman@28029	112	assume "scale a x = scale b x"
huffman@28029	113	hence "scale (a - b) x = 0"
huffman@28029	114	by (simp add: scale_left_diff_distrib)
huffman@28029	115	hence "a - b = 0" by (simp add: nonzero)
huffman@28029	116	thus "a = b" by (simp only: right_minus_eq)
huffman@28029	117	qed
huffman@28029	118
huffman@28029	119	lemma scale_cancel_left:
huffman@28029	120	"scale a x = scale a y \<longleftrightarrow> x = y \<or> a = 0"
huffman@28029	121	by (auto intro: scale_left_imp_eq)
huffman@28029	122
huffman@28029	123	lemma scale_cancel_right:
huffman@28029	124	"scale a x = scale b x \<longleftrightarrow> a = b \<or> x = 0"
huffman@28029	125	by (auto intro: scale_right_imp_eq)
huffman@28029	126
huffman@28029	127	end
huffman@28029	128
huffman@20504	129	subsection {* Real vector spaces *}
huffman@20504	130
haftmann@29608	131	class scaleR =
haftmann@25062	132	fixes scaleR :: "real \<Rightarrow> 'a \<Rightarrow> 'a" (infixr "*\<^sub>R" 75)
haftmann@24748	133	begin
huffman@20504	134
huffman@20763	135	abbreviation
haftmann@25062	136	divideR :: "'a \<Rightarrow> real \<Rightarrow> 'a" (infixl "'/\<^sub>R" 70)
haftmann@24748	137	where
haftmann@25062	138	"x /\<^sub>R r == scaleR (inverse r) x"
haftmann@24748	139
haftmann@24748	140	end
haftmann@24748	141
haftmann@24588	142	class real_vector = scaleR + ab_group_add +
haftmann@25062	143	assumes scaleR_right_distrib: "scaleR a (x + y) = scaleR a x + scaleR a y"
haftmann@25062	144	and scaleR_left_distrib: "scaleR (a + b) x = scaleR a x + scaleR b x"
huffman@30070	145	and scaleR_scaleR: "scaleR a (scaleR b x) = scaleR (a * b) x"
huffman@30070	146	and scaleR_one: "scaleR 1 x = x"
huffman@20504	147
wenzelm@30729	148	interpretation real_vector:
ballarin@29229	149	vector_space "scaleR :: real \<Rightarrow> 'a \<Rightarrow> 'a::real_vector"
huffman@28009	150	apply unfold_locales
huffman@28009	151	apply (rule scaleR_right_distrib)
huffman@28009	152	apply (rule scaleR_left_distrib)
huffman@28009	153	apply (rule scaleR_scaleR)
huffman@28009	154	apply (rule scaleR_one)
huffman@28009	155	done
huffman@28009	156
huffman@28009	157	text {* Recover original theorem names *}
huffman@28009	158
huffman@28009	159	lemmas scaleR_left_commute = real_vector.scale_left_commute
huffman@28009	160	lemmas scaleR_zero_left = real_vector.scale_zero_left
huffman@28009	161	lemmas scaleR_minus_left = real_vector.scale_minus_left
huffman@28009	162	lemmas scaleR_left_diff_distrib = real_vector.scale_left_diff_distrib
huffman@28009	163	lemmas scaleR_zero_right = real_vector.scale_zero_right
huffman@28009	164	lemmas scaleR_minus_right = real_vector.scale_minus_right
huffman@28009	165	lemmas scaleR_right_diff_distrib = real_vector.scale_right_diff_distrib
huffman@28009	166	lemmas scaleR_eq_0_iff = real_vector.scale_eq_0_iff
huffman@28009	167	lemmas scaleR_left_imp_eq = real_vector.scale_left_imp_eq
huffman@28009	168	lemmas scaleR_right_imp_eq = real_vector.scale_right_imp_eq
huffman@28009	169	lemmas scaleR_cancel_left = real_vector.scale_cancel_left
huffman@28009	170	lemmas scaleR_cancel_right = real_vector.scale_cancel_right
huffman@28009	171
huffman@31285	172	lemma scaleR_minus1_left [simp]:
huffman@31285	173	fixes x :: "'a::real_vector"
huffman@31285	174	shows "scaleR (-1) x = - x"
huffman@31285	175	using scaleR_minus_left [of 1 x] by simp
huffman@31285	176
haftmann@24588	177	class real_algebra = real_vector + ring +
haftmann@25062	178	assumes mult_scaleR_left [simp]: "scaleR a x * y = scaleR a (x * y)"
haftmann@25062	179	and mult_scaleR_right [simp]: "x * scaleR a y = scaleR a (x * y)"
huffman@20504	180
haftmann@24588	181	class real_algebra_1 = real_algebra + ring_1
huffman@20554	182
haftmann@24588	183	class real_div_algebra = real_algebra_1 + division_ring
huffman@20584	184
haftmann@24588	185	class real_field = real_div_algebra + field
huffman@20584	186
huffman@30069	187	instantiation real :: real_field
huffman@30069	188	begin
huffman@30069	189
huffman@30069	190	definition
huffman@30069	191	real_scaleR_def [simp]: "scaleR a x = a * x"
huffman@30069	192
huffman@30070	193	instance proof
huffman@30070	194	qed (simp_all add: algebra_simps)
huffman@20554	195
huffman@30069	196	end
huffman@30069	197
wenzelm@30729	198	interpretation scaleR_left: additive "(\<lambda>a. scaleR a x::'a::real_vector)"
haftmann@28823	199	proof qed (rule scaleR_left_distrib)
huffman@20504	200
wenzelm@30729	201	interpretation scaleR_right: additive "(\<lambda>x. scaleR a x::'a::real_vector)"
haftmann@28823	202	proof qed (rule scaleR_right_distrib)
huffman@20504	203
huffman@20584	204	lemma nonzero_inverse_scaleR_distrib:
huffman@21809	205	fixes x :: "'a::real_div_algebra" shows
huffman@21809	206	"\<lbrakk>a \<noteq> 0; x \<noteq> 0\<rbrakk> \<Longrightarrow> inverse (scaleR a x) = scaleR (inverse a) (inverse x)"
huffman@20763	207	by (rule inverse_unique, simp)
huffman@20584	208
huffman@20584	209	lemma inverse_scaleR_distrib:
huffman@20584	210	fixes x :: "'a::{real_div_algebra,division_by_zero}"
huffman@21809	211	shows "inverse (scaleR a x) = scaleR (inverse a) (inverse x)"
huffman@20584	212	apply (case_tac "a = 0", simp)
huffman@20584	213	apply (case_tac "x = 0", simp)
huffman@20584	214	apply (erule (1) nonzero_inverse_scaleR_distrib)
huffman@20584	215	done
huffman@20584	216
huffman@20554	217
huffman@20554	218	subsection {* Embedding of the Reals into any @{text real_algebra_1}:
huffman@20554	219	@{term of_real} *}
huffman@20554	220
huffman@20554	221	definition
wenzelm@21404	222	of_real :: "real \<Rightarrow> 'a::real_algebra_1" where
huffman@21809	223	"of_real r = scaleR r 1"
huffman@20554	224
huffman@21809	225	lemma scaleR_conv_of_real: "scaleR r x = of_real r * x"
huffman@20763	226	by (simp add: of_real_def)
huffman@20763	227
huffman@20554	228	lemma of_real_0 [simp]: "of_real 0 = 0"
huffman@20554	229	by (simp add: of_real_def)
huffman@20554	230
huffman@20554	231	lemma of_real_1 [simp]: "of_real 1 = 1"
huffman@20554	232	by (simp add: of_real_def)
huffman@20554	233
huffman@20554	234	lemma of_real_add [simp]: "of_real (x + y) = of_real x + of_real y"
huffman@20554	235	by (simp add: of_real_def scaleR_left_distrib)
huffman@20554	236
huffman@20554	237	lemma of_real_minus [simp]: "of_real (- x) = - of_real x"
huffman@20554	238	by (simp add: of_real_def)
huffman@20554	239
huffman@20554	240	lemma of_real_diff [simp]: "of_real (x - y) = of_real x - of_real y"
huffman@20554	241	by (simp add: of_real_def scaleR_left_diff_distrib)
huffman@20554	242
huffman@20554	243	lemma of_real_mult [simp]: "of_real (x * y) = of_real x * of_real y"
huffman@20763	244	by (simp add: of_real_def mult_commute)
huffman@20554	245
huffman@20584	246	lemma nonzero_of_real_inverse:
huffman@20584	247	"x \<noteq> 0 \<Longrightarrow> of_real (inverse x) =
huffman@20584	248	inverse (of_real x :: 'a::real_div_algebra)"
huffman@20584	249	by (simp add: of_real_def nonzero_inverse_scaleR_distrib)
huffman@20584	250
huffman@20584	251	lemma of_real_inverse [simp]:
huffman@20584	252	"of_real (inverse x) =
huffman@20584	253	inverse (of_real x :: 'a::{real_div_algebra,division_by_zero})"
huffman@20584	254	by (simp add: of_real_def inverse_scaleR_distrib)
huffman@20584	255
huffman@20584	256	lemma nonzero_of_real_divide:
huffman@20584	257	"y \<noteq> 0 \<Longrightarrow> of_real (x / y) =
huffman@20584	258	(of_real x / of_real y :: 'a::real_field)"
huffman@20584	259	by (simp add: divide_inverse nonzero_of_real_inverse)
huffman@20722	260
huffman@20722	261	lemma of_real_divide [simp]:
huffman@20584	262	"of_real (x / y) =
huffman@20584	263	(of_real x / of_real y :: 'a::{real_field,division_by_zero})"
huffman@20584	264	by (simp add: divide_inverse)
huffman@20584	265
huffman@20722	266	lemma of_real_power [simp]:
haftmann@31017	267	"of_real (x ^ n) = (of_real x :: 'a::{real_algebra_1}) ^ n"
huffman@30273	268	by (induct n) simp_all
huffman@20722	269
huffman@20554	270	lemma of_real_eq_iff [simp]: "(of_real x = of_real y) = (x = y)"
huffman@20554	271	by (simp add: of_real_def scaleR_cancel_right)
huffman@20554	272
huffman@20584	273	lemmas of_real_eq_0_iff [simp] = of_real_eq_iff [of _ 0, simplified]
huffman@20554	274
huffman@20554	275	lemma of_real_eq_id [simp]: "of_real = (id :: real \<Rightarrow> real)"
huffman@20554	276	proof
huffman@20554	277	fix r
huffman@20554	278	show "of_real r = id r"
huffman@22973	279	by (simp add: of_real_def)
huffman@20554	280	qed
huffman@20554	281
huffman@20554	282	text{Collapse nested embeddings}
huffman@20554	283	lemma of_real_of_nat_eq [simp]: "of_real (of_nat n) = of_nat n"
wenzelm@20772	284	by (induct n) auto
huffman@20554	285
huffman@20554	286	lemma of_real_of_int_eq [simp]: "of_real (of_int z) = of_int z"
huffman@20554	287	by (cases z rule: int_diff_cases, simp)
huffman@20554	288
huffman@20554	289	lemma of_real_number_of_eq:
huffman@20554	290	"of_real (number_of w) = (number_of w :: 'a::{number_ring,real_algebra_1})"
huffman@20554	291	by (simp add: number_of_eq)
huffman@20554	292
huffman@22912	293	text{Every real algebra has characteristic zero}
huffman@22912	294	instance real_algebra_1 < ring_char_0
huffman@22912	295	proof
huffman@23282	296	fix m n :: nat
huffman@23282	297	have "(of_real (of_nat m) = (of_real (of_nat n)::'a)) = (m = n)"
huffman@23282	298	by (simp only: of_real_eq_iff of_nat_eq_iff)
huffman@23282	299	thus "(of_nat m = (of_nat n::'a)) = (m = n)"
huffman@23282	300	by (simp only: of_real_of_nat_eq)
huffman@22912	301	qed
huffman@22912	302
huffman@27553	303	instance real_field < field_char_0 ..
huffman@27553	304
huffman@20554	305
huffman@20554	306	subsection {* The Set of Real Numbers *}
huffman@20554	307
wenzelm@20772	308	definition
wenzelm@21404	309	Reals :: "'a::real_algebra_1 set" where
huffman@30070	310	[code del]: "Reals = range of_real"
huffman@20554	311
wenzelm@21210	312	notation (xsymbols)
huffman@20554	313	Reals ("\<real>")
huffman@20554	314
huffman@21809	315	lemma Reals_of_real [simp]: "of_real r \<in> Reals"
huffman@20554	316	by (simp add: Reals_def)
huffman@20554	317
huffman@21809	318	lemma Reals_of_int [simp]: "of_int z \<in> Reals"
huffman@21809	319	by (subst of_real_of_int_eq [symmetric], rule Reals_of_real)
huffman@20718	320
huffman@21809	321	lemma Reals_of_nat [simp]: "of_nat n \<in> Reals"
huffman@21809	322	by (subst of_real_of_nat_eq [symmetric], rule Reals_of_real)
huffman@21809	323
huffman@21809	324	lemma Reals_number_of [simp]:
huffman@21809	325	"(number_of w::'a::{number_ring,real_algebra_1}) \<in> Reals"
huffman@21809	326	by (subst of_real_number_of_eq [symmetric], rule Reals_of_real)
huffman@20718	327
huffman@20554	328	lemma Reals_0 [simp]: "0 \<in> Reals"
huffman@20554	329	apply (unfold Reals_def)
huffman@20554	330	apply (rule range_eqI)
huffman@20554	331	apply (rule of_real_0 [symmetric])
huffman@20554	332	done
huffman@20554	333
huffman@20554	334	lemma Reals_1 [simp]: "1 \<in> Reals"
huffman@20554	335	apply (unfold Reals_def)
huffman@20554	336	apply (rule range_eqI)
huffman@20554	337	apply (rule of_real_1 [symmetric])
huffman@20554	338	done
huffman@20554	339
huffman@20584	340	lemma Reals_add [simp]: "\<lbrakk>a \<in> Reals; b \<in> Reals\<rbrakk> \<Longrightarrow> a + b \<in> Reals"
huffman@20554	341	apply (auto simp add: Reals_def)
huffman@20554	342	apply (rule range_eqI)
huffman@20554	343	apply (rule of_real_add [symmetric])
huffman@20554	344	done
huffman@20554	345
huffman@20584	346	lemma Reals_minus [simp]: "a \<in> Reals \<Longrightarrow> - a \<in> Reals"
huffman@20584	347	apply (auto simp add: Reals_def)
huffman@20584	348	apply (rule range_eqI)
huffman@20584	349	apply (rule of_real_minus [symmetric])
huffman@20584	350	done
huffman@20584	351
huffman@20584	352	lemma Reals_diff [simp]: "\<lbrakk>a \<in> Reals; b \<in> Reals\<rbrakk> \<Longrightarrow> a - b \<in> Reals"
huffman@20584	353	apply (auto simp add: Reals_def)
huffman@20584	354	apply (rule range_eqI)
huffman@20584	355	apply (rule of_real_diff [symmetric])
huffman@20584	356	done
huffman@20584	357
huffman@20584	358	lemma Reals_mult [simp]: "\<lbrakk>a \<in> Reals; b \<in> Reals\<rbrakk> \<Longrightarrow> a * b \<in> Reals"
huffman@20554	359	apply (auto simp add: Reals_def)
huffman@20554	360	apply (rule range_eqI)
huffman@20554	361	apply (rule of_real_mult [symmetric])
huffman@20554	362	done
huffman@20554	363
huffman@20584	364	lemma nonzero_Reals_inverse:
huffman@20584	365	fixes a :: "'a::real_div_algebra"
huffman@20584	366	shows "\<lbrakk>a \<in> Reals; a \<noteq> 0\<rbrakk> \<Longrightarrow> inverse a \<in> Reals"
huffman@20584	367	apply (auto simp add: Reals_def)
huffman@20584	368	apply (rule range_eqI)
huffman@20584	369	apply (erule nonzero_of_real_inverse [symmetric])
huffman@20584	370	done
huffman@20584	371
huffman@20584	372	lemma Reals_inverse [simp]:
huffman@20584	373	fixes a :: "'a::{real_div_algebra,division_by_zero}"
huffman@20584	374	shows "a \<in> Reals \<Longrightarrow> inverse a \<in> Reals"
huffman@20584	375	apply (auto simp add: Reals_def)
huffman@20584	376	apply (rule range_eqI)
huffman@20584	377	apply (rule of_real_inverse [symmetric])
huffman@20584	378	done
huffman@20584	379
huffman@20584	380	lemma nonzero_Reals_divide:
huffman@20584	381	fixes a b :: "'a::real_field"
huffman@20584	382	shows "\<lbrakk>a \<in> Reals; b \<in> Reals; b \<noteq> 0\<rbrakk> \<Longrightarrow> a / b \<in> Reals"
huffman@20584	383	apply (auto simp add: Reals_def)
huffman@20584	384	apply (rule range_eqI)
huffman@20584	385	apply (erule nonzero_of_real_divide [symmetric])
huffman@20584	386	done
huffman@20584	387
huffman@20584	388	lemma Reals_divide [simp]:
huffman@20584	389	fixes a b :: "'a::{real_field,division_by_zero}"
huffman@20584	390	shows "\<lbrakk>a \<in> Reals; b \<in> Reals\<rbrakk> \<Longrightarrow> a / b \<in> Reals"
huffman@20584	391	apply (auto simp add: Reals_def)
huffman@20584	392	apply (rule range_eqI)
huffman@20584	393	apply (rule of_real_divide [symmetric])
huffman@20584	394	done
huffman@20584	395
huffman@20722	396	lemma Reals_power [simp]:
haftmann@31017	397	fixes a :: "'a::{real_algebra_1}"
huffman@20722	398	shows "a \<in> Reals \<Longrightarrow> a ^ n \<in> Reals"
huffman@20722	399	apply (auto simp add: Reals_def)
huffman@20722	400	apply (rule range_eqI)
huffman@20722	401	apply (rule of_real_power [symmetric])
huffman@20722	402	done
huffman@20722	403
huffman@20554	404	lemma Reals_cases [cases set: Reals]:
huffman@20554	405	assumes "q \<in> \<real>"
huffman@20554	406	obtains (of_real) r where "q = of_real r"
huffman@20554	407	unfolding Reals_def
huffman@20554	408	proof -
huffman@20554	409	from `q \<in> \<real>` have "q \<in> range of_real" unfolding Reals_def .
huffman@20554	410	then obtain r where "q = of_real r" ..
huffman@20554	411	then show thesis ..
huffman@20554	412	qed
huffman@20554	413
huffman@20554	414	lemma Reals_induct [case_names of_real, induct set: Reals]:
huffman@20554	415	"q \<in> \<real> \<Longrightarrow> (\<And>r. P (of_real r)) \<Longrightarrow> P q"
huffman@20554	416	by (rule Reals_cases) auto
huffman@20554	417
huffman@20504	418
huffman@31413	419	subsection {* Topological spaces *}
huffman@31413	420
huffman@31417	421	class topo =
huffman@31417	422	fixes topo :: "'a set set"
huffman@31413	423
huffman@31417	424	class topological_space = topo +
huffman@31417	425	assumes topo_UNIV: "UNIV \<in> topo"
huffman@31417	426	assumes topo_Int: "A \<in> topo \<Longrightarrow> B \<in> topo \<Longrightarrow> A \<inter> B \<in> topo"
huffman@31417	427	assumes topo_Union: "T \<subseteq> topo \<Longrightarrow> \<Union>T \<in> topo"
huffman@31413	428
huffman@31413	429
huffman@31289	430	subsection {* Metric spaces *}
huffman@31289	431
huffman@31289	432	class dist =
huffman@31289	433	fixes dist :: "'a \<Rightarrow> 'a \<Rightarrow> real"
huffman@31289	434
huffman@31417	435	class topo_dist = topo + dist +
huffman@31417	436	assumes topo_dist: "topo = {S. \<forall>x\<in>S. \<exists>e>0. \<forall>y. dist y x < e \<longrightarrow> y \<in> S}"
huffman@31413	437
huffman@31417	438	class metric_space = topo_dist +
huffman@31289	439	assumes dist_eq_0_iff [simp]: "dist x y = 0 \<longleftrightarrow> x = y"
huffman@31289	440	assumes dist_triangle2: "dist x y \<le> dist x z + dist y z"
huffman@31289	441	begin
huffman@31289	442
huffman@31289	443	lemma dist_self [simp]: "dist x x = 0"
huffman@31289	444	by simp
huffman@31289	445
huffman@31289	446	lemma zero_le_dist [simp]: "0 \<le> dist x y"
huffman@31289	447	using dist_triangle2 [of x x y] by simp
huffman@31289	448
huffman@31289	449	lemma zero_less_dist_iff: "0 < dist x y \<longleftrightarrow> x \<noteq> y"
huffman@31289	450	by (simp add: less_le)
huffman@31289	451
huffman@31289	452	lemma dist_not_less_zero [simp]: "\<not> dist x y < 0"
huffman@31289	453	by (simp add: not_less)
huffman@31289	454
huffman@31289	455	lemma dist_le_zero_iff [simp]: "dist x y \<le> 0 \<longleftrightarrow> x = y"
huffman@31289	456	by (simp add: le_less)
huffman@31289	457
huffman@31289	458	lemma dist_commute: "dist x y = dist y x"
huffman@31289	459	proof (rule order_antisym)
huffman@31289	460	show "dist x y \<le> dist y x"
huffman@31289	461	using dist_triangle2 [of x y x] by simp
huffman@31289	462	show "dist y x \<le> dist x y"
huffman@31289	463	using dist_triangle2 [of y x y] by simp
huffman@31289	464	qed
huffman@31289	465
huffman@31289	466	lemma dist_triangle: "dist x z \<le> dist x y + dist y z"
huffman@31289	467	using dist_triangle2 [of x z y] by (simp add: dist_commute)
huffman@31289	468
huffman@31413	469	subclass topological_space
huffman@31413	470	proof
huffman@31413	471	have "\<exists>e::real. 0 < e"
huffman@31413	472	by (fast intro: zero_less_one)
huffman@31417	473	then show "UNIV \<in> topo"
huffman@31417	474	unfolding topo_dist by simp
huffman@31413	475	next
huffman@31417	476	fix A B assume "A \<in> topo" "B \<in> topo"
huffman@31417	477	then show "A \<inter> B \<in> topo"
huffman@31417	478	unfolding topo_dist
huffman@31413	479	apply clarify
huffman@31413	480	apply (drule (1) bspec)+
huffman@31413	481	apply (clarify, rename_tac r s)
huffman@31413	482	apply (rule_tac x="min r s" in exI, simp)
huffman@31413	483	done
huffman@31413	484	next
huffman@31417	485	fix T assume "T \<subseteq> topo" thus "\<Union>T \<in> topo"
huffman@31417	486	unfolding topo_dist by fast
huffman@31413	487	qed
huffman@31413	488
huffman@31289	489	end
huffman@31289	490
huffman@31289	491
huffman@20504	492	subsection {* Real normed vector spaces *}
huffman@20504	493
haftmann@29608	494	class norm =
huffman@22636	495	fixes norm :: "'a \<Rightarrow> real"
huffman@20504	496
huffman@24520	497	class sgn_div_norm = scaleR + norm + sgn +
haftmann@25062	498	assumes sgn_div_norm: "sgn x = x /\<^sub>R norm x"
nipkow@24506	499
huffman@31289	500	class dist_norm = dist + norm + minus +
huffman@31289	501	assumes dist_norm: "dist x y = norm (x - y)"
huffman@31289	502
huffman@31417	503	class real_normed_vector = real_vector + sgn_div_norm + dist_norm + topo_dist +
haftmann@24588	504	assumes norm_ge_zero [simp]: "0 \<le> norm x"
haftmann@25062	505	and norm_eq_zero [simp]: "norm x = 0 \<longleftrightarrow> x = 0"
haftmann@25062	506	and norm_triangle_ineq: "norm (x + y) \<le> norm x + norm y"
haftmann@24588	507	and norm_scaleR: "norm (scaleR a x) = \<bar>a\<bar> * norm x"
huffman@20504	508
haftmann@24588	509	class real_normed_algebra = real_algebra + real_normed_vector +
haftmann@25062	510	assumes norm_mult_ineq: "norm (x * y) \<le> norm x * norm y"
huffman@20504	511
haftmann@24588	512	class real_normed_algebra_1 = real_algebra_1 + real_normed_algebra +
haftmann@25062	513	assumes norm_one [simp]: "norm 1 = 1"
huffman@22852	514
haftmann@24588	515	class real_normed_div_algebra = real_div_algebra + real_normed_vector +
haftmann@25062	516	assumes norm_mult: "norm (x * y) = norm x * norm y"
huffman@20504	517
haftmann@24588	518	class real_normed_field = real_field + real_normed_div_algebra
huffman@20584	519
huffman@22852	520	instance real_normed_div_algebra < real_normed_algebra_1
huffman@20554	521	proof
huffman@20554	522	fix x y :: 'a
huffman@20554	523	show "norm (x * y) \<le> norm x * norm y"
huffman@20554	524	by (simp add: norm_mult)
huffman@22852	525	next
huffman@22852	526	have "norm (1 * 1::'a) = norm (1::'a) * norm (1::'a)"
huffman@22852	527	by (rule norm_mult)
huffman@22852	528	thus "norm (1::'a) = 1" by simp
huffman@20554	529	qed
huffman@20554	530
huffman@30069	531	instantiation real :: real_normed_field
huffman@30069	532	begin
huffman@30069	533
huffman@31413	534	definition real_norm_def [simp]:
huffman@31413	535	"norm r = \<bar>r\<bar>"
huffman@30069	536
huffman@31413	537	definition dist_real_def:
huffman@31413	538	"dist x y = \<bar>x - y\<bar>"
huffman@31413	539
huffman@31419	540	definition topo_real_def [code del]:
huffman@31417	541	"topo = {S::real set. \<forall>x\<in>S. \<exists>e>0. \<forall>y. dist y x < e \<longrightarrow> y \<in> S}"
huffman@31289	542
huffman@30069	543	instance
huffman@22852	544	apply (intro_classes, unfold real_norm_def real_scaleR_def)
huffman@31289	545	apply (rule dist_real_def)
nipkow@24506	546	apply (simp add: real_sgn_def)
huffman@31417	547	apply (rule topo_real_def)
huffman@20554	548	apply (rule abs_ge_zero)
huffman@20554	549	apply (rule abs_eq_0)
huffman@20554	550	apply (rule abs_triangle_ineq)
huffman@22852	551	apply (rule abs_mult)
huffman@20554	552	apply (rule abs_mult)
huffman@20554	553	done
huffman@20504	554
huffman@30069	555	end
huffman@30069	556
huffman@22852	557	lemma norm_zero [simp]: "norm (0::'a::real_normed_vector) = 0"
huffman@20504	558	by simp
huffman@20504	559
huffman@22852	560	lemma zero_less_norm_iff [simp]:
huffman@22852	561	fixes x :: "'a::real_normed_vector"
huffman@22852	562	shows "(0 < norm x) = (x \<noteq> 0)"
huffman@20504	563	by (simp add: order_less_le)
huffman@20504	564
huffman@22852	565	lemma norm_not_less_zero [simp]:
huffman@22852	566	fixes x :: "'a::real_normed_vector"
huffman@22852	567	shows "\<not> norm x < 0"
huffman@20828	568	by (simp add: linorder_not_less)
huffman@20828	569
huffman@22852	570	lemma norm_le_zero_iff [simp]:
huffman@22852	571	fixes x :: "'a::real_normed_vector"
huffman@22852	572	shows "(norm x \<le> 0) = (x = 0)"
huffman@20828	573	by (simp add: order_le_less)
huffman@20828	574
huffman@20504	575	lemma norm_minus_cancel [simp]:
huffman@20584	576	fixes x :: "'a::real_normed_vector"
huffman@20584	577	shows "norm (- x) = norm x"
huffman@20504	578	proof -
huffman@21809	579	have "norm (- x) = norm (scaleR (- 1) x)"
huffman@20504	580	by (simp only: scaleR_minus_left scaleR_one)
huffman@20533	581	also have "\<dots> = \<bar>- 1\<bar> * norm x"
huffman@20504	582	by (rule norm_scaleR)
huffman@20504	583	finally show ?thesis by simp
huffman@20504	584	qed
huffman@20504	585
huffman@20504	586	lemma norm_minus_commute:
huffman@20584	587	fixes a b :: "'a::real_normed_vector"
huffman@20584	588	shows "norm (a - b) = norm (b - a)"
huffman@20504	589	proof -
huffman@22898	590	have "norm (- (b - a)) = norm (b - a)"
huffman@22898	591	by (rule norm_minus_cancel)
huffman@22898	592	thus ?thesis by simp
huffman@20504	593	qed
huffman@20504	594
huffman@20504	595	lemma norm_triangle_ineq2:
huffman@20584	596	fixes a b :: "'a::real_normed_vector"
huffman@20533	597	shows "norm a - norm b \<le> norm (a - b)"
huffman@20504	598	proof -
huffman@20533	599	have "norm (a - b + b) \<le> norm (a - b) + norm b"
huffman@20504	600	by (rule norm_triangle_ineq)
huffman@22898	601	thus ?thesis by simp
huffman@20504	602	qed
huffman@20504	603
huffman@20584	604	lemma norm_triangle_ineq3:
huffman@20584	605	fixes a b :: "'a::real_normed_vector"
huffman@20584	606	shows "\<bar>norm a - norm b\<bar> \<le> norm (a - b)"
huffman@20584	607	apply (subst abs_le_iff)
huffman@20584	608	apply auto
huffman@20584	609	apply (rule norm_triangle_ineq2)
huffman@20584	610	apply (subst norm_minus_commute)
huffman@20584	611	apply (rule norm_triangle_ineq2)
huffman@20584	612	done
huffman@20584	613
huffman@20504	614	lemma norm_triangle_ineq4:
huffman@20584	615	fixes a b :: "'a::real_normed_vector"
huffman@20533	616	shows "norm (a - b) \<le> norm a + norm b"
huffman@20504	617	proof -
huffman@22898	618	have "norm (a + - b) \<le> norm a + norm (- b)"
huffman@20504	619	by (rule norm_triangle_ineq)
huffman@22898	620	thus ?thesis
huffman@22898	621	by (simp only: diff_minus norm_minus_cancel)
huffman@22898	622	qed
huffman@22898	623
huffman@22898	624	lemma norm_diff_ineq:
huffman@22898	625	fixes a b :: "'a::real_normed_vector"
huffman@22898	626	shows "norm a - norm b \<le> norm (a + b)"
huffman@22898	627	proof -
huffman@22898	628	have "norm a - norm (- b) \<le> norm (a - - b)"
huffman@22898	629	by (rule norm_triangle_ineq2)
huffman@22898	630	thus ?thesis by simp
huffman@20504	631	qed
huffman@20504	632
huffman@20551	633	lemma norm_diff_triangle_ineq:
huffman@20551	634	fixes a b c d :: "'a::real_normed_vector"
huffman@20551	635	shows "norm ((a + b) - (c + d)) \<le> norm (a - c) + norm (b - d)"
huffman@20551	636	proof -
huffman@20551	637	have "norm ((a + b) - (c + d)) = norm ((a - c) + (b - d))"
huffman@20551	638	by (simp add: diff_minus add_ac)
huffman@20551	639	also have "\<dots> \<le> norm (a - c) + norm (b - d)"
huffman@20551	640	by (rule norm_triangle_ineq)
huffman@20551	641	finally show ?thesis .
huffman@20551	642	qed
huffman@20551	643
huffman@22857	644	lemma abs_norm_cancel [simp]:
huffman@22857	645	fixes a :: "'a::real_normed_vector"
huffman@22857	646	shows "\<bar>norm a\<bar> = norm a"
huffman@22857	647	by (rule abs_of_nonneg [OF norm_ge_zero])
huffman@22857	648
huffman@22880	649	lemma norm_add_less:
huffman@22880	650	fixes x y :: "'a::real_normed_vector"
huffman@22880	651	shows "\<lbrakk>norm x < r; norm y < s\<rbrakk> \<Longrightarrow> norm (x + y) < r + s"
huffman@22880	652	by (rule order_le_less_trans [OF norm_triangle_ineq add_strict_mono])
huffman@22880	653
huffman@22880	654	lemma norm_mult_less:
huffman@22880	655	fixes x y :: "'a::real_normed_algebra"
huffman@22880	656	shows "\<lbrakk>norm x < r; norm y < s\<rbrakk> \<Longrightarrow> norm (x * y) < r * s"
huffman@22880	657	apply (rule order_le_less_trans [OF norm_mult_ineq])
huffman@22880	658	apply (simp add: mult_strict_mono')
huffman@22880	659	done
huffman@22880	660
huffman@22857	661	lemma norm_of_real [simp]:
huffman@22857	662	"norm (of_real r :: 'a::real_normed_algebra_1) = \<bar>r\<bar>"
huffman@22852	663	unfolding of_real_def by (simp add: norm_scaleR)
huffman@20560	664
huffman@22876	665	lemma norm_number_of [simp]:
huffman@22876	666	"norm (number_of w::'a::{number_ring,real_normed_algebra_1})
huffman@22876	667	= \<bar>number_of w\<bar>"
huffman@22876	668	by (subst of_real_number_of_eq [symmetric], rule norm_of_real)
huffman@22876	669
huffman@22876	670	lemma norm_of_int [simp]:
huffman@22876	671	"norm (of_int z::'a::real_normed_algebra_1) = \<bar>of_int z\<bar>"
huffman@22876	672	by (subst of_real_of_int_eq [symmetric], rule norm_of_real)
huffman@22876	673
huffman@22876	674	lemma norm_of_nat [simp]:
huffman@22876	675	"norm (of_nat n::'a::real_normed_algebra_1) = of_nat n"
huffman@22876	676	apply (subst of_real_of_nat_eq [symmetric])
huffman@22876	677	apply (subst norm_of_real, simp)
huffman@22876	678	done
huffman@22876	679
huffman@20504	680	lemma nonzero_norm_inverse:
huffman@20504	681	fixes a :: "'a::real_normed_div_algebra"
huffman@20533	682	shows "a \<noteq> 0 \<Longrightarrow> norm (inverse a) = inverse (norm a)"
huffman@20504	683	apply (rule inverse_unique [symmetric])
huffman@20504	684	apply (simp add: norm_mult [symmetric])
huffman@20504	685	done
huffman@20504	686
huffman@20504	687	lemma norm_inverse:
huffman@20504	688	fixes a :: "'a::{real_normed_div_algebra,division_by_zero}"
huffman@20533	689	shows "norm (inverse a) = inverse (norm a)"
huffman@20504	690	apply (case_tac "a = 0", simp)
huffman@20504	691	apply (erule nonzero_norm_inverse)
huffman@20504	692	done
huffman@20504	693
huffman@20584	694	lemma nonzero_norm_divide:
huffman@20584	695	fixes a b :: "'a::real_normed_field"
huffman@20584	696	shows "b \<noteq> 0 \<Longrightarrow> norm (a / b) = norm a / norm b"
huffman@20584	697	by (simp add: divide_inverse norm_mult nonzero_norm_inverse)
huffman@20584	698
huffman@20584	699	lemma norm_divide:
huffman@20584	700	fixes a b :: "'a::{real_normed_field,division_by_zero}"
huffman@20584	701	shows "norm (a / b) = norm a / norm b"
huffman@20584	702	by (simp add: divide_inverse norm_mult norm_inverse)
huffman@20584	703
huffman@22852	704	lemma norm_power_ineq:
haftmann@31017	705	fixes x :: "'a::{real_normed_algebra_1}"
huffman@22852	706	shows "norm (x ^ n) \<le> norm x ^ n"
huffman@22852	707	proof (induct n)
huffman@22852	708	case 0 show "norm (x ^ 0) \<le> norm x ^ 0" by simp
huffman@22852	709	next
huffman@22852	710	case (Suc n)
huffman@22852	711	have "norm (x * x ^ n) \<le> norm x * norm (x ^ n)"
huffman@22852	712	by (rule norm_mult_ineq)
huffman@22852	713	also from Suc have "\<dots> \<le> norm x * norm x ^ n"
huffman@22852	714	using norm_ge_zero by (rule mult_left_mono)
huffman@22852	715	finally show "norm (x ^ Suc n) \<le> norm x ^ Suc n"
huffman@30273	716	by simp
huffman@22852	717	qed
huffman@22852	718
huffman@20684	719	lemma norm_power:
haftmann@31017	720	fixes x :: "'a::{real_normed_div_algebra}"
huffman@20684	721	shows "norm (x ^ n) = norm x ^ n"
huffman@30273	722	by (induct n) (simp_all add: norm_mult)
huffman@20684	723
huffman@31289	724	text {* Every normed vector space is a metric space. *}
huffman@31285	725
huffman@31289	726	instance real_normed_vector < metric_space
huffman@31289	727	proof
huffman@31289	728	fix x y :: 'a show "dist x y = 0 \<longleftrightarrow> x = y"
huffman@31289	729	unfolding dist_norm by simp
huffman@31289	730	next
huffman@31289	731	fix x y z :: 'a show "dist x y \<le> dist x z + dist y z"
huffman@31289	732	unfolding dist_norm
huffman@31289	733	using norm_triangle_ineq4 [of "x - z" "y - z"] by simp
huffman@31289	734	qed
huffman@31285	735
huffman@31446	736	subsection {* Extra type constraints *}
huffman@31446	737
huffman@31446	738	text {* Only allow @{term dist} in class @{text metric_space}. *}
huffman@31446	739
huffman@31446	740	setup {* Sign.add_const_constraint
huffman@31446	741	(@{const_name dist}, SOME @{typ "'a::metric_space \<Rightarrow> 'a \<Rightarrow> real"}) *}
huffman@31446	742
huffman@31446	743	text {* Only allow @{term norm} in class @{text real_normed_vector}. *}
huffman@31446	744
huffman@31446	745	setup {* Sign.add_const_constraint
huffman@31446	746	(@{const_name norm}, SOME @{typ "'a::real_normed_vector \<Rightarrow> real"}) *}
huffman@31446	747
huffman@31285	748
huffman@22972	749	subsection {* Sign function *}
huffman@22972	750
nipkow@24506	751	lemma norm_sgn:
nipkow@24506	752	"norm (sgn(x::'a::real_normed_vector)) = (if x = 0 then 0 else 1)"
nipkow@24506	753	by (simp add: sgn_div_norm norm_scaleR)
huffman@22972	754
nipkow@24506	755	lemma sgn_zero [simp]: "sgn(0::'a::real_normed_vector) = 0"
nipkow@24506	756	by (simp add: sgn_div_norm)
huffman@22972	757
nipkow@24506	758	lemma sgn_zero_iff: "(sgn(x::'a::real_normed_vector) = 0) = (x = 0)"
nipkow@24506	759	by (simp add: sgn_div_norm)
huffman@22972	760
nipkow@24506	761	lemma sgn_minus: "sgn (- x) = - sgn(x::'a::real_normed_vector)"
nipkow@24506	762	by (simp add: sgn_div_norm)
huffman@22972	763
nipkow@24506	764	lemma sgn_scaleR:
nipkow@24506	765	"sgn (scaleR r x) = scaleR (sgn r) (sgn(x::'a::real_normed_vector))"
nipkow@24506	766	by (simp add: sgn_div_norm norm_scaleR mult_ac)
huffman@22973	767
huffman@22972	768	lemma sgn_one [simp]: "sgn (1::'a::real_normed_algebra_1) = 1"
nipkow@24506	769	by (simp add: sgn_div_norm)
huffman@22972	770
huffman@22972	771	lemma sgn_of_real:
huffman@22972	772	"sgn (of_real r::'a::real_normed_algebra_1) = of_real (sgn r)"
huffman@22972	773	unfolding of_real_def by (simp only: sgn_scaleR sgn_one)
huffman@22972	774
huffman@22973	775	lemma sgn_mult:
huffman@22973	776	fixes x y :: "'a::real_normed_div_algebra"
huffman@22973	777	shows "sgn (x * y) = sgn x * sgn y"
nipkow@24506	778	by (simp add: sgn_div_norm norm_mult mult_commute)
huffman@22973	779
huffman@22972	780	lemma real_sgn_eq: "sgn (x::real) = x / \<bar>x\<bar>"
nipkow@24506	781	by (simp add: sgn_div_norm divide_inverse)
huffman@22972	782
huffman@22972	783	lemma real_sgn_pos: "0 < (x::real) \<Longrightarrow> sgn x = 1"
huffman@22972	784	unfolding real_sgn_eq by simp
huffman@22972	785
huffman@22972	786	lemma real_sgn_neg: "(x::real) < 0 \<Longrightarrow> sgn x = -1"
huffman@22972	787	unfolding real_sgn_eq by simp
huffman@22972	788
huffman@22972	789
huffman@22442	790	subsection {* Bounded Linear and Bilinear Operators *}
huffman@22442	791
huffman@22442	792	locale bounded_linear = additive +
huffman@22442	793	constrains f :: "'a::real_normed_vector \<Rightarrow> 'b::real_normed_vector"
huffman@22442	794	assumes scaleR: "f (scaleR r x) = scaleR r (f x)"
huffman@22442	795	assumes bounded: "\<exists>K. \<forall>x. norm (f x) \<le> norm x * K"
huffman@27443	796	begin
huffman@22442	797
huffman@27443	798	lemma pos_bounded:
huffman@22442	799	"\<exists>K>0. \<forall>x. norm (f x) \<le> norm x * K"
huffman@22442	800	proof -
huffman@22442	801	obtain K where K: "\<And>x. norm (f x) \<le> norm x * K"
huffman@22442	802	using bounded by fast
huffman@22442	803	show ?thesis
huffman@22442	804	proof (intro exI impI conjI allI)
huffman@22442	805	show "0 < max 1 K"
huffman@22442	806	by (rule order_less_le_trans [OF zero_less_one le_maxI1])
huffman@22442	807	next
huffman@22442	808	fix x
huffman@22442	809	have "norm (f x) \<le> norm x * K" using K .
huffman@22442	810	also have "\<dots> \<le> norm x * max 1 K"
huffman@22442	811	by (rule mult_left_mono [OF le_maxI2 norm_ge_zero])
huffman@22442	812	finally show "norm (f x) \<le> norm x * max 1 K" .
huffman@22442	813	qed
huffman@22442	814	qed
huffman@22442	815
huffman@27443	816	lemma nonneg_bounded:
huffman@22442	817	"\<exists>K\<ge>0. \<forall>x. norm (f x) \<le> norm x * K"
huffman@22442	818	proof -
huffman@22442	819	from pos_bounded
huffman@22442	820	show ?thesis by (auto intro: order_less_imp_le)
huffman@22442	821	qed
huffman@22442	822
huffman@27443	823	end
huffman@27443	824
huffman@22442	825	locale bounded_bilinear =
huffman@22442	826	fixes prod :: "['a::real_normed_vector, 'b::real_normed_vector]
huffman@22442	827	\<Rightarrow> 'c::real_normed_vector"
huffman@22442	828	(infixl "**" 70)
huffman@22442	829	assumes add_left: "prod (a + a') b = prod a b + prod a' b"
huffman@22442	830	assumes add_right: "prod a (b + b') = prod a b + prod a b'"
huffman@22442	831	assumes scaleR_left: "prod (scaleR r a) b = scaleR r (prod a b)"
huffman@22442	832	assumes scaleR_right: "prod a (scaleR r b) = scaleR r (prod a b)"
huffman@22442	833	assumes bounded: "\<exists>K. \<forall>a b. norm (prod a b) \<le> norm a * norm b * K"
huffman@27443	834	begin
huffman@22442	835
huffman@27443	836	lemma pos_bounded:
huffman@22442	837	"\<exists>K>0. \<forall>a b. norm (a ** b) \<le> norm a * norm b * K"
huffman@22442	838	apply (cut_tac bounded, erule exE)
huffman@22442	839	apply (rule_tac x="max 1 K" in exI, safe)
huffman@22442	840	apply (rule order_less_le_trans [OF zero_less_one le_maxI1])
huffman@22442	841	apply (drule spec, drule spec, erule order_trans)
huffman@22442	842	apply (rule mult_left_mono [OF le_maxI2])
huffman@22442	843	apply (intro mult_nonneg_nonneg norm_ge_zero)
huffman@22442	844	done
huffman@22442	845
huffman@27443	846	lemma nonneg_bounded:
huffman@22442	847	"\<exists>K\<ge>0. \<forall>a b. norm (a ** b) \<le> norm a * norm b * K"
huffman@22442	848	proof -
huffman@22442	849	from pos_bounded
huffman@22442	850	show ?thesis by (auto intro: order_less_imp_le)
huffman@22442	851	qed
huffman@22442	852
huffman@27443	853	lemma additive_right: "additive (\<lambda>b. prod a b)"
huffman@22442	854	by (rule additive.intro, rule add_right)
huffman@22442	855
huffman@27443	856	lemma additive_left: "additive (\<lambda>a. prod a b)"
huffman@22442	857	by (rule additive.intro, rule add_left)
huffman@22442	858
huffman@27443	859	lemma zero_left: "prod 0 b = 0"
huffman@22442	860	by (rule additive.zero [OF additive_left])
huffman@22442	861
huffman@27443	862	lemma zero_right: "prod a 0 = 0"
huffman@22442	863	by (rule additive.zero [OF additive_right])
huffman@22442	864
huffman@27443	865	lemma minus_left: "prod (- a) b = - prod a b"
huffman@22442	866	by (rule additive.minus [OF additive_left])
huffman@22442	867
huffman@27443	868	lemma minus_right: "prod a (- b) = - prod a b"
huffman@22442	869	by (rule additive.minus [OF additive_right])
huffman@22442	870
huffman@27443	871	lemma diff_left:
huffman@22442	872	"prod (a - a') b = prod a b - prod a' b"
huffman@22442	873	by (rule additive.diff [OF additive_left])
huffman@22442	874
huffman@27443	875	lemma diff_right:
huffman@22442	876	"prod a (b - b') = prod a b - prod a b'"
huffman@22442	877	by (rule additive.diff [OF additive_right])
huffman@22442	878
huffman@27443	879	lemma bounded_linear_left:
huffman@22442	880	"bounded_linear (\<lambda>a. a ** b)"
huffman@22442	881	apply (unfold_locales)
huffman@22442	882	apply (rule add_left)
huffman@22442	883	apply (rule scaleR_left)
huffman@22442	884	apply (cut_tac bounded, safe)
huffman@22442	885	apply (rule_tac x="norm b * K" in exI)
huffman@22442	886	apply (simp add: mult_ac)
huffman@22442	887	done
huffman@22442	888
huffman@27443	889	lemma bounded_linear_right:
huffman@22442	890	"bounded_linear (\<lambda>b. a ** b)"
huffman@22442	891	apply (unfold_locales)
huffman@22442	892	apply (rule add_right)
huffman@22442	893	apply (rule scaleR_right)
huffman@22442	894	apply (cut_tac bounded, safe)
huffman@22442	895	apply (rule_tac x="norm a * K" in exI)
huffman@22442	896	apply (simp add: mult_ac)
huffman@22442	897	done
huffman@22442	898
huffman@27443	899	lemma prod_diff_prod:
huffman@22442	900	"(x y - a b) = (x - a) (y - b) + (x - a) b + a ** (y - b)"
huffman@22442	901	by (simp add: diff_left diff_right)
huffman@22442	902
huffman@27443	903	end
huffman@27443	904
wenzelm@30729	905	interpretation mult:
ballarin@29229	906	bounded_bilinear "op * :: 'a \<Rightarrow> 'a \<Rightarrow> 'a::real_normed_algebra"
huffman@22442	907	apply (rule bounded_bilinear.intro)
huffman@22442	908	apply (rule left_distrib)
huffman@22442	909	apply (rule right_distrib)
huffman@22442	910	apply (rule mult_scaleR_left)
huffman@22442	911	apply (rule mult_scaleR_right)
huffman@22442	912	apply (rule_tac x="1" in exI)
huffman@22442	913	apply (simp add: norm_mult_ineq)
huffman@22442	914	done
huffman@22442	915
wenzelm@30729	916	interpretation mult_left:
ballarin@29229	917	bounded_linear "(\<lambda>x::'a::real_normed_algebra. x * y)"
huffman@23127	918	by (rule mult.bounded_linear_left)
huffman@22442	919
wenzelm@30729	920	interpretation mult_right:
ballarin@29229	921	bounded_linear "(\<lambda>y::'a::real_normed_algebra. x * y)"
huffman@23127	922	by (rule mult.bounded_linear_right)
huffman@23127	923
wenzelm@30729	924	interpretation divide:
ballarin@29229	925	bounded_linear "(\<lambda>x::'a::real_normed_field. x / y)"
huffman@23127	926	unfolding divide_inverse by (rule mult.bounded_linear_left)
huffman@23120	927
wenzelm@30729	928	interpretation scaleR: bounded_bilinear "scaleR"
huffman@22442	929	apply (rule bounded_bilinear.intro)
huffman@22442	930	apply (rule scaleR_left_distrib)
huffman@22442	931	apply (rule scaleR_right_distrib)
huffman@22973	932	apply simp
huffman@22442	933	apply (rule scaleR_left_commute)
huffman@22442	934	apply (rule_tac x="1" in exI)
huffman@22442	935	apply (simp add: norm_scaleR)
huffman@22442	936	done
huffman@22442	937
wenzelm@30729	938	interpretation scaleR_left: bounded_linear "\<lambda>r. scaleR r x"
huffman@23127	939	by (rule scaleR.bounded_linear_left)
huffman@23127	940
wenzelm@30729	941	interpretation scaleR_right: bounded_linear "\<lambda>x. scaleR r x"
huffman@23127	942	by (rule scaleR.bounded_linear_right)
huffman@23127	943
wenzelm@30729	944	interpretation of_real: bounded_linear "\<lambda>r. of_real r"
huffman@23127	945	unfolding of_real_def by (rule scaleR.bounded_linear_left)
huffman@22625	946
huffman@20504	947	end

author	huffman
	Sat Jun 06 09:11:12 2009 -0700 (2009-06-06)
changeset 31488	5691ccb8d6b5
parent 31446	2d91b2416de8
child 31490	c350f3ad6b0d
permissions	-rw-r--r--