isabelle: src/HOL/Analysis/Complete_Measure.thy@f3b905b2eee2 (annotated)

63627 6ddb43c6b711 rename HOL-Multivariate_Analysis to HOL-Analysis. hoelzl parents: 63626 diff changeset	1	(* Title: HOL/Analysis/Complete_Measure.thy
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	2	Author: Robert Himmelmann, Johannes Hoelzl, TU Muenchen
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	3	*)
41983 2dc6e382a58b standardized headers; wenzelm parents: 41981 diff changeset	4
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	5	theory Complete_Measure
63626 44ce6b524ff3 move measure theory from HOL-Probability to HOL-Multivariate_Analysis hoelzl parents: 62975 diff changeset	6	imports Bochner_Integration
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	7	begin
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	8
63940 0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	9	locale complete_measure =
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	10	fixes M :: "'a measure"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	11	assumes complete: "\<And>A B. B \<subseteq> A \<Longrightarrow> A \<in> null_sets M \<Longrightarrow> B \<in> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	12
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	13	definition
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	14	"split_completion M A p = (if A \<in> sets M then p = (A, {}) else
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	15	\<exists>N'. A = fst p \<union> snd p \<and> fst p \<inter> snd p = {} \<and> fst p \<in> sets M \<and> snd p \<subseteq> N' \<and> N' \<in> null_sets M)"
41689 3e39b0e730d6 the measure valuation is again part of the measure_space type, instead of an explicit parameter to the locale; hoelzl parents: 41097 diff changeset	16
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	17	definition
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	18	"main_part M A = fst (Eps (split_completion M A))"
41689 3e39b0e730d6 the measure valuation is again part of the measure_space type, instead of an explicit parameter to the locale; hoelzl parents: 41097 diff changeset	19
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	20	definition
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	21	"null_part M A = snd (Eps (split_completion M A))"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	22
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	23	definition completion :: "'a measure \<Rightarrow> 'a measure" where
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	24	"completion M = measure_of (space M) { S \<union> N \|S N N'. S \<in> sets M \<and> N' \<in> null_sets M \<and> N \<subseteq> N' }
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	25	(emeasure M \<circ> main_part M)"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	26
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	27	lemma completion_into_space:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	28	"{ S \<union> N \|S N N'. S \<in> sets M \<and> N' \<in> null_sets M \<and> N \<subseteq> N' } \<subseteq> Pow (space M)"
50244 de72bbe42190 qualified interpretation of sigma_algebra, to avoid name clashes immler parents: 47694 diff changeset	29	using sets.sets_into_space by auto
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	30
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	31	lemma space_completion[simp]: "space (completion M) = space M"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	32	unfolding completion_def using space_measure_of[OF completion_into_space] by simp
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	33
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	34	lemma completionI:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	35	assumes "A = S \<union> N" "N \<subseteq> N'" "N' \<in> null_sets M" "S \<in> sets M"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	36	shows "A \<in> { S \<union> N \|S N N'. S \<in> sets M \<and> N' \<in> null_sets M \<and> N \<subseteq> N' }"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	37	using assms by auto
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	38
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	39	lemma completionE:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	40	assumes "A \<in> { S \<union> N \|S N N'. S \<in> sets M \<and> N' \<in> null_sets M \<and> N \<subseteq> N' }"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	41	obtains S N N' where "A = S \<union> N" "N \<subseteq> N'" "N' \<in> null_sets M" "S \<in> sets M"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	42	using assms by auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	43
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	44	lemma sigma_algebra_completion:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	45	"sigma_algebra (space M) { S \<union> N \|S N N'. S \<in> sets M \<and> N' \<in> null_sets M \<and> N \<subseteq> N' }"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	46	(is "sigma_algebra _ ?A")
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	47	unfolding sigma_algebra_iff2
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	48	proof (intro conjI ballI allI impI)
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	49	show "?A \<subseteq> Pow (space M)"
50244 de72bbe42190 qualified interpretation of sigma_algebra, to avoid name clashes immler parents: 47694 diff changeset	50	using sets.sets_into_space by auto
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	51	next
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	52	show "{} \<in> ?A" by auto
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	53	next
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	54	let ?C = "space M"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	55	fix A assume "A \<in> ?A" from completionE[OF this] guess S N N' .
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	56	then show "space M - A \<in> ?A"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	57	by (intro completionI[of _ "(?C - S) \<inter> (?C - N')" "(?C - S) \<inter> N' \<inter> (?C - N)"]) auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	58	next
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	59	fix A :: "nat \<Rightarrow> 'a set" assume A: "range A \<subseteq> ?A"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	60	then have "\<forall>n. \<exists>S N N'. A n = S \<union> N \<and> S \<in> sets M \<and> N' \<in> null_sets M \<and> N \<subseteq> N'"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	61	by (auto simp: image_subset_iff)
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	62	from choice[OF this] guess S ..
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	63	from choice[OF this] guess N ..
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	64	from choice[OF this] guess N' ..
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	65	then show "UNION UNIV A \<in> ?A"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	66	using null_sets_UN[of N']
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	67	by (intro completionI[of _ "UNION UNIV S" "UNION UNIV N" "UNION UNIV N'"]) auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	68	qed
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	69
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	70	lemma sets_completion:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	71	"sets (completion M) = { S \<union> N \|S N N'. S \<in> sets M \<and> N' \<in> null_sets M \<and> N \<subseteq> N' }"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	72	using sigma_algebra.sets_measure_of_eq[OF sigma_algebra_completion] by (simp add: completion_def)
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	73
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	74	lemma sets_completionE:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	75	assumes "A \<in> sets (completion M)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	76	obtains S N N' where "A = S \<union> N" "N \<subseteq> N'" "N' \<in> null_sets M" "S \<in> sets M"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	77	using assms unfolding sets_completion by auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	78
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	79	lemma sets_completionI:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	80	assumes "A = S \<union> N" "N \<subseteq> N'" "N' \<in> null_sets M" "S \<in> sets M"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	81	shows "A \<in> sets (completion M)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	82	using assms unfolding sets_completion by auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	83
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	84	lemma sets_completionI_sets[intro, simp]:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	85	"A \<in> sets M \<Longrightarrow> A \<in> sets (completion M)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	86	unfolding sets_completion by force
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	87
63958 02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	88	lemma measurable_completion: "f \<in> M \<rightarrow>\<^sub>M N \<Longrightarrow> f \<in> completion M \<rightarrow>\<^sub>M N"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	89	by (auto simp: measurable_def)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	90
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	91	lemma null_sets_completion:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	92	assumes "N' \<in> null_sets M" "N \<subseteq> N'" shows "N \<in> sets (completion M)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	93	using assms by (intro sets_completionI[of N "{}" N N']) auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	94
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	95	lemma split_completion:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	96	assumes "A \<in> sets (completion M)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	97	shows "split_completion M A (main_part M A, null_part M A)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	98	proof cases
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	99	assume "A \<in> sets M" then show ?thesis
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	100	by (simp add: split_completion_def[abs_def] main_part_def null_part_def)
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	101	next
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	102	assume nA: "A \<notin> sets M"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	103	show ?thesis
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	104	unfolding main_part_def null_part_def if_not_P[OF nA]
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	105	proof (rule someI2_ex)
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	106	from assms[THEN sets_completionE] guess S N N' . note A = this
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	107	let ?P = "(S, N - S)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	108	show "\<exists>p. split_completion M A p"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	109	unfolding split_completion_def if_not_P[OF nA] using A
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	110	proof (intro exI conjI)
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	111	show "A = fst ?P \<union> snd ?P" using A by auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	112	show "snd ?P \<subseteq> N'" using A by auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	113	qed auto
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	114	qed auto
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	115	qed
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	116
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	117	lemma
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	118	assumes "S \<in> sets (completion M)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	119	shows main_part_sets[intro, simp]: "main_part M S \<in> sets M"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	120	and main_part_null_part_Un[simp]: "main_part M S \<union> null_part M S = S"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	121	and main_part_null_part_Int[simp]: "main_part M S \<inter> null_part M S = {}"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	122	using split_completion[OF assms]
62390 842917225d56 more canonical names nipkow parents: 62343 diff changeset	123	by (auto simp: split_completion_def split: if_split_asm)
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	124
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	125	lemma main_part[simp]: "S \<in> sets M \<Longrightarrow> main_part M S = S"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	126	using split_completion[of S M]
62390 842917225d56 more canonical names nipkow parents: 62343 diff changeset	127	by (auto simp: split_completion_def split: if_split_asm)
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	128
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	129	lemma null_part:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	130	assumes "S \<in> sets (completion M)" shows "\<exists>N. N\<in>null_sets M \<and> null_part M S \<subseteq> N"
62390 842917225d56 more canonical names nipkow parents: 62343 diff changeset	131	using split_completion[OF assms] by (auto simp: split_completion_def split: if_split_asm)
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	132
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	133	lemma null_part_sets[intro, simp]:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	134	assumes "S \<in> sets M" shows "null_part M S \<in> sets M" "emeasure M (null_part M S) = 0"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	135	proof -
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	136	have S: "S \<in> sets (completion M)" using assms by auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	137	have "S - main_part M S \<in> sets M" using assms by auto
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	138	moreover
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	139	from main_part_null_part_Un[OF S] main_part_null_part_Int[OF S]
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	140	have "S - main_part M S = null_part M S" by auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	141	ultimately show sets: "null_part M S \<in> sets M" by auto
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	142	from null_part[OF S] guess N ..
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	143	with emeasure_eq_0[of N _ "null_part M S"] sets
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	144	show "emeasure M (null_part M S) = 0" by auto
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	145	qed
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	146
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	147	lemma emeasure_main_part_UN:
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	148	fixes S :: "nat \<Rightarrow> 'a set"
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	149	assumes "range S \<subseteq> sets (completion M)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	150	shows "emeasure M (main_part M (\<Union>i. (S i))) = emeasure M (\<Union>i. main_part M (S i))"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	151	proof -
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	152	have S: "\<And>i. S i \<in> sets (completion M)" using assms by auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	153	then have UN: "(\<Union>i. S i) \<in> sets (completion M)" by auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	154	have "\<forall>i. \<exists>N. N \<in> null_sets M \<and> null_part M (S i) \<subseteq> N"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	155	using null_part[OF S] by auto
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	156	from choice[OF this] guess N .. note N = this
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	157	then have UN_N: "(\<Union>i. N i) \<in> null_sets M" by (intro null_sets_UN) auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	158	have "(\<Union>i. S i) \<in> sets (completion M)" using S by auto
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	159	from null_part[OF this] guess N' .. note N' = this
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	160	let ?N = "(\<Union>i. N i) \<union> N'"
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	161	have null_set: "?N \<in> null_sets M" using N' UN_N by (intro null_sets.Un) auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	162	have "main_part M (\<Union>i. S i) \<union> ?N = (main_part M (\<Union>i. S i) \<union> null_part M (\<Union>i. S i)) \<union> ?N"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	163	using N' by auto
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	164	also have "\<dots> = (\<Union>i. main_part M (S i) \<union> null_part M (S i)) \<union> ?N"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	165	unfolding main_part_null_part_Un[OF S] main_part_null_part_Un[OF UN] by auto
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	166	also have "\<dots> = (\<Union>i. main_part M (S i)) \<union> ?N"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	167	using N by auto
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	168	finally have *: "main_part M (\<Union>i. S i) \<union> ?N = (\<Union>i. main_part M (S i)) \<union> ?N" .
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	169	have "emeasure M (main_part M (\<Union>i. S i)) = emeasure M (main_part M (\<Union>i. S i) \<union> ?N)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	170	using null_set UN by (intro emeasure_Un_null_set[symmetric]) auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	171	also have "\<dots> = emeasure M ((\<Union>i. main_part M (S i)) \<union> ?N)"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	172	unfolding * ..
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	173	also have "\<dots> = emeasure M (\<Union>i. main_part M (S i))"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	174	using null_set S by (intro emeasure_Un_null_set) auto
41689 3e39b0e730d6 the measure valuation is again part of the measure_space type, instead of an explicit parameter to the locale; hoelzl parents: 41097 diff changeset	175	finally show ?thesis .
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	176	qed
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	177
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	178	lemma emeasure_completion[simp]:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	179	assumes S: "S \<in> sets (completion M)" shows "emeasure (completion M) S = emeasure M (main_part M S)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	180	proof (subst emeasure_measure_of[OF completion_def completion_into_space])
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	181	let ?\<mu> = "emeasure M \<circ> main_part M"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	182	show "S \<in> sets (completion M)" "?\<mu> S = emeasure M (main_part M S) " using S by simp_all
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	183	show "positive (sets (completion M)) ?\<mu>"
62975 1d066f6ab25d Probability: move emeasure and nn_integral from ereal to ennreal hoelzl parents: 62390 diff changeset	184	by (simp add: positive_def)
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	185	show "countably_additive (sets (completion M)) ?\<mu>"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	186	proof (intro countably_additiveI)
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	187	fix A :: "nat \<Rightarrow> 'a set" assume A: "range A \<subseteq> sets (completion M)" "disjoint_family A"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	188	have "disjoint_family (\<lambda>i. main_part M (A i))"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	189	proof (intro disjoint_family_on_bisimulation[OF A(2)])
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	190	fix n m assume "A n \<inter> A m = {}"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	191	then have "(main_part M (A n) \<union> null_part M (A n)) \<inter> (main_part M (A m) \<union> null_part M (A m)) = {}"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	192	using A by (subst (1 2) main_part_null_part_Un) auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	193	then show "main_part M (A n) \<inter> main_part M (A m) = {}" by auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	194	qed
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	195	then have "(\<Sum>n. emeasure M (main_part M (A n))) = emeasure M (\<Union>i. main_part M (A i))"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	196	using A by (auto intro!: suminf_emeasure)
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	197	then show "(\<Sum>n. ?\<mu> (A n)) = ?\<mu> (UNION UNIV A)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	198	by (simp add: completion_def emeasure_main_part_UN[OF A(1)])
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	199	qed
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	200	qed
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	201
63968 4359400adfe7 HOL-Analysis: the image of a negligible set under a Lipschitz continuous function is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63959 diff changeset	202	lemma measure_completion[simp]: "S \<in> sets M \<Longrightarrow> measure (completion M) S = measure M S"
4359400adfe7 HOL-Analysis: the image of a negligible set under a Lipschitz continuous function is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63959 diff changeset	203	unfolding measure_def by auto
4359400adfe7 HOL-Analysis: the image of a negligible set under a Lipschitz continuous function is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63959 diff changeset	204
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	205	lemma emeasure_completion_UN:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	206	"range S \<subseteq> sets (completion M) \<Longrightarrow>
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	207	emeasure (completion M) (\<Union>i::nat. (S i)) = emeasure M (\<Union>i. main_part M (S i))"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	208	by (subst emeasure_completion) (auto simp add: emeasure_main_part_UN)
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	209
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	210	lemma emeasure_completion_Un:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	211	assumes S: "S \<in> sets (completion M)" and T: "T \<in> sets (completion M)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	212	shows "emeasure (completion M) (S \<union> T) = emeasure M (main_part M S \<union> main_part M T)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	213	proof (subst emeasure_completion)
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	214	have UN: "(\<Union>i. binary (main_part M S) (main_part M T) i) = (\<Union>i. main_part M (binary S T i))"
62390 842917225d56 more canonical names nipkow parents: 62343 diff changeset	215	unfolding binary_def by (auto split: if_split_asm)
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	216	show "emeasure M (main_part M (S \<union> T)) = emeasure M (main_part M S \<union> main_part M T)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	217	using emeasure_main_part_UN[of "binary S T" M] assms
62343 24106dc44def prefer abbreviations for compound operators INFIMUM and SUPREMUM haftmann parents: 61808 diff changeset	218	by (simp add: range_binary_eq, simp add: Un_range_binary UN)
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	219	qed (auto intro: S T)
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	220
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	221	lemma sets_completionI_sub:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	222	assumes N: "N' \<in> null_sets M" "N \<subseteq> N'"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	223	shows "N \<in> sets (completion M)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	224	using assms by (intro sets_completionI[of _ "{}" N N']) auto
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	225
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	226	lemma completion_ex_simple_function:
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	227	assumes f: "simple_function (completion M) f"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	228	shows "\<exists>f'. simple_function M f' \<and> (AE x in M. f x = f' x)"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	229	proof -
46731 5302e932d1e5 avoid undeclared variables in let bindings; wenzelm parents: 43920 diff changeset	230	let ?F = "\<lambda>x. f -` {x} \<inter> space M"
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	231	have F: "\<And>x. ?F x \<in> sets (completion M)" and fin: "finite (f`space M)"
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	232	using simple_functionD[OF f] simple_functionD[OF f] by simp_all
05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	233	have "\<forall>x. \<exists>N. N \<in> null_sets M \<and> null_part M (?F x) \<subseteq> N"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	234	using F null_part by auto
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	235	from choice[OF this] obtain N where
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	236	N: "\<And>x. null_part M (?F x) \<subseteq> N x" "\<And>x. N x \<in> null_sets M" by auto
46731 5302e932d1e5 avoid undeclared variables in let bindings; wenzelm parents: 43920 diff changeset	237	let ?N = "\<Union>x\<in>f`space M. N x"
5302e932d1e5 avoid undeclared variables in let bindings; wenzelm parents: 43920 diff changeset	238	let ?f' = "\<lambda>x. if x \<in> ?N then undefined else f x"
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	239	have sets: "?N \<in> null_sets M" using N fin by (intro null_sets.finite_UN) auto
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	240	show ?thesis unfolding simple_function_def
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	241	proof (safe intro!: exI[of _ ?f'])
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	242	have "?f' ` space M \<subseteq> f`space M \<union> {undefined}" by auto
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	243	from finite_subset[OF this] simple_functionD(1)[OF f]
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	244	show "finite (?f' ` space M)" by auto
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	245	next
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	246	fix x assume "x \<in> space M"
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	247	have "?f' -` {?f' x} \<inter> space M =
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	248	(if x \<in> ?N then ?F undefined \<union> ?N
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	249	else if f x = undefined then ?F (f x) \<union> ?N
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	250	else ?F (f x) - ?N)"
62390 842917225d56 more canonical names nipkow parents: 62343 diff changeset	251	using N(2) sets.sets_into_space by (auto split: if_split_asm simp: null_sets_def)
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	252	moreover { fix y have "?F y \<union> ?N \<in> sets M"
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	253	proof cases
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	254	assume y: "y \<in> f`space M"
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	255	have "?F y \<union> ?N = (main_part M (?F y) \<union> null_part M (?F y)) \<union> ?N"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	256	using main_part_null_part_Un[OF F] by auto
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	257	also have "\<dots> = main_part M (?F y) \<union> ?N"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	258	using y N by auto
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	259	finally show ?thesis
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	260	using F sets by auto
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	261	next
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	262	assume "y \<notin> f`space M" then have "?F y = {}" by auto
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	263	then show ?thesis using sets by auto
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	264	qed }
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	265	moreover {
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	266	have "?F (f x) - ?N = main_part M (?F (f x)) \<union> null_part M (?F (f x)) - ?N"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	267	using main_part_null_part_Un[OF F] by auto
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	268	also have "\<dots> = main_part M (?F (f x)) - ?N"
61808 fc1556774cfe isabelle update_cartouches -c -t; wenzelm parents: 58587 diff changeset	269	using N \<open>x \<in> space M\<close> by auto
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	270	finally have "?F (f x) - ?N \<in> sets M"
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	271	using F sets by auto }
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	272	ultimately show "?f' -` {?f' x} \<inter> space M \<in> sets M" by auto
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	273	next
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	274	show "AE x in M. f x = ?f' x"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	275	by (rule AE_I', rule sets) auto
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	276	qed
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	277	qed
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	278
62975 1d066f6ab25d Probability: move emeasure and nn_integral from ereal to ennreal hoelzl parents: 62390 diff changeset	279	lemma completion_ex_borel_measurable:
1d066f6ab25d Probability: move emeasure and nn_integral from ereal to ennreal hoelzl parents: 62390 diff changeset	280	fixes g :: "'a \<Rightarrow> ennreal"
1d066f6ab25d Probability: move emeasure and nn_integral from ereal to ennreal hoelzl parents: 62390 diff changeset	281	assumes g: "g \<in> borel_measurable (completion M)"
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	282	shows "\<exists>g'\<in>borel_measurable M. (AE x in M. g x = g' x)"
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	283	proof -
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	284	from g[THEN borel_measurable_implies_simple_function_sequence'] guess f . note f = this
41981 cdf7693bbe08 reworked Probability theory: measures are not type restricted to positive extended reals hoelzl parents: 41959 diff changeset	285	from this(1)[THEN completion_ex_simple_function]
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	286	have "\<forall>i. \<exists>f'. simple_function M f' \<and> (AE x in M. f i x = f' x)" ..
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	287	from this[THEN choice] obtain f' where
41689 3e39b0e730d6 the measure valuation is again part of the measure_space type, instead of an explicit parameter to the locale; hoelzl parents: 41097 diff changeset	288	sf: "\<And>i. simple_function M (f' i)" and
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	289	AE: "\<forall>i. AE x in M. f i x = f' i x" by auto
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	290	show ?thesis
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	291	proof (intro bexI)
41981 cdf7693bbe08 reworked Probability theory: measures are not type restricted to positive extended reals hoelzl parents: 41959 diff changeset	292	from AE[unfolded AE_all_countable[symmetric]]
47694 05663f75964c reworked Probability theory hoelzl parents: 46731 diff changeset	293	show "AE x in M. g x = (SUP i. f' i x)" (is "AE x in M. g x = ?f x")
41705 1100512e16d8 add auto support for AE_mp hoelzl parents: 41689 diff changeset	294	proof (elim AE_mp, safe intro!: AE_I2)
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	295	fix x assume eq: "\<forall>i. f i x = f' i x"
41981 cdf7693bbe08 reworked Probability theory: measures are not type restricted to positive extended reals hoelzl parents: 41959 diff changeset	296	moreover have "g x = (SUP i. f i x)"
62975 1d066f6ab25d Probability: move emeasure and nn_integral from ereal to ennreal hoelzl parents: 62390 diff changeset	297	unfolding f by (auto split: split_max)
41981 cdf7693bbe08 reworked Probability theory: measures are not type restricted to positive extended reals hoelzl parents: 41959 diff changeset	298	ultimately show "g x = ?f x" by auto
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	299	qed
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	300	show "?f \<in> borel_measurable M"
56949 d1a937cbf858 clean up Lebesgue integration hoelzl parents: 50244 diff changeset	301	using sf[THEN borel_measurable_simple_function] by auto
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	302	qed
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	303	qed
de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	304
58587 5484f6079bcd add type for probability mass functions, i.e. discrete probability distribution hoelzl parents: 56993 diff changeset	305	lemma null_sets_completionI: "N \<in> null_sets M \<Longrightarrow> N \<in> null_sets (completion M)"
5484f6079bcd add type for probability mass functions, i.e. discrete probability distribution hoelzl parents: 56993 diff changeset	306	by (auto simp: null_sets_def)
5484f6079bcd add type for probability mass functions, i.e. discrete probability distribution hoelzl parents: 56993 diff changeset	307
5484f6079bcd add type for probability mass functions, i.e. discrete probability distribution hoelzl parents: 56993 diff changeset	308	lemma AE_completion: "(AE x in M. P x) \<Longrightarrow> (AE x in completion M. P x)"
5484f6079bcd add type for probability mass functions, i.e. discrete probability distribution hoelzl parents: 56993 diff changeset	309	unfolding eventually_ae_filter by (auto intro: null_sets_completionI)
5484f6079bcd add type for probability mass functions, i.e. discrete probability distribution hoelzl parents: 56993 diff changeset	310
5484f6079bcd add type for probability mass functions, i.e. discrete probability distribution hoelzl parents: 56993 diff changeset	311	lemma null_sets_completion_iff: "N \<in> sets M \<Longrightarrow> N \<in> null_sets (completion M) \<longleftrightarrow> N \<in> null_sets M"
5484f6079bcd add type for probability mass functions, i.e. discrete probability distribution hoelzl parents: 56993 diff changeset	312	by (auto simp: null_sets_def)
5484f6079bcd add type for probability mass functions, i.e. discrete probability distribution hoelzl parents: 56993 diff changeset	313
63940 0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	314	lemma sets_completion_AE: "(AE x in M. \<not> P x) \<Longrightarrow> Measurable.pred (completion M) P"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	315	unfolding pred_def sets_completion eventually_ae_filter
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	316	by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	317
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	318	lemma null_sets_completion_iff2:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	319	"A \<in> null_sets (completion M) \<longleftrightarrow> (\<exists>N'\<in>null_sets M. A \<subseteq> N')"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	320	proof safe
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	321	assume "A \<in> null_sets (completion M)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	322	then have A: "A \<in> sets (completion M)" and "main_part M A \<in> null_sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	323	by (auto simp: null_sets_def)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	324	moreover obtain N where "N \<in> null_sets M" "null_part M A \<subseteq> N"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	325	using null_part[OF A] by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	326	ultimately show "\<exists>N'\<in>null_sets M. A \<subseteq> N'"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	327	proof (intro bexI)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	328	show "A \<subseteq> N \<union> main_part M A"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	329	using \<open>null_part M A \<subseteq> N\<close> by (subst main_part_null_part_Un[OF A, symmetric]) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	330	qed auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	331	next
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	332	fix N assume "N \<in> null_sets M" "A \<subseteq> N"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	333	then have "A \<in> sets (completion M)" and N: "N \<in> sets M" "A \<subseteq> N" "emeasure M N = 0"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	334	by (auto intro: null_sets_completion)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	335	moreover have "emeasure (completion M) A = 0"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	336	using N by (intro emeasure_eq_0[of N _ A]) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	337	ultimately show "A \<in> null_sets (completion M)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	338	by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	339	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	340
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	341	lemma null_sets_completion_subset:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	342	"B \<subseteq> A \<Longrightarrow> A \<in> null_sets (completion M) \<Longrightarrow> B \<in> null_sets (completion M)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	343	unfolding null_sets_completion_iff2 by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	344
63958 02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	345	interpretation completion: complete_measure "completion M" for M
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	346	proof
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	347	show "B \<subseteq> A \<Longrightarrow> A \<in> null_sets (completion M) \<Longrightarrow> B \<in> sets (completion M)" for B A
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	348	using null_sets_completion_subset[of B A M] by (simp add: null_sets_def)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	349	qed
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	350
63940 0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	351	lemma null_sets_restrict_space:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	352	"\<Omega> \<in> sets M \<Longrightarrow> A \<in> null_sets (restrict_space M \<Omega>) \<longleftrightarrow> A \<subseteq> \<Omega> \<and> A \<in> null_sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	353	by (auto simp: null_sets_def emeasure_restrict_space sets_restrict_space)
63941 f353674c2528 move absolutely_integrable_on to Equivalence_Lebesgue_Henstock_Integration, now based on the Lebesgue integral hoelzl parents: 63940 diff changeset	354
63940 0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	355	lemma completion_ex_borel_measurable_real:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	356	fixes g :: "'a \<Rightarrow> real"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	357	assumes g: "g \<in> borel_measurable (completion M)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	358	shows "\<exists>g'\<in>borel_measurable M. (AE x in M. g x = g' x)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	359	proof -
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	360	have "(\<lambda>x. ennreal (g x)) \<in> completion M \<rightarrow>\<^sub>M borel" "(\<lambda>x. ennreal (- g x)) \<in> completion M \<rightarrow>\<^sub>M borel"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	361	using g by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	362	from this[THEN completion_ex_borel_measurable]
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	363	obtain pf nf :: "'a \<Rightarrow> ennreal"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	364	where [measurable]: "nf \<in> M \<rightarrow>\<^sub>M borel" "pf \<in> M \<rightarrow>\<^sub>M borel"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	365	and ae: "AE x in M. pf x = ennreal (g x)" "AE x in M. nf x = ennreal (- g x)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	366	by (auto simp: eq_commute)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	367	then have "AE x in M. pf x = ennreal (g x) \<and> nf x = ennreal (- g x)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	368	by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	369	then obtain N where "N \<in> null_sets M" "{x\<in>space M. pf x \<noteq> ennreal (g x) \<and> nf x \<noteq> ennreal (- g x)} \<subseteq> N"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	370	by (auto elim!: AE_E)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	371	show ?thesis
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	372	proof
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	373	let ?F = "\<lambda>x. indicator (space M - N) x * (enn2real (pf x) - enn2real (nf x))"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	374	show "?F \<in> M \<rightarrow>\<^sub>M borel"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	375	using \<open>N \<in> null_sets M\<close> by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	376	show "AE x in M. g x = ?F x"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	377	using \<open>N \<in> null_sets M\<close>[THEN AE_not_in] ae AE_space
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	378	apply eventually_elim
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	379	subgoal for x
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	380	by (cases "0::real" "g x" rule: linorder_le_cases) (auto simp: ennreal_neg)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	381	done
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	382	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	383	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	384
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	385	lemma simple_function_completion: "simple_function M f \<Longrightarrow> simple_function (completion M) f"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	386	by (simp add: simple_function_def)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	387
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	388	lemma simple_integral_completion:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	389	"simple_function M f \<Longrightarrow> simple_integral (completion M) f = simple_integral M f"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	390	unfolding simple_integral_def by simp
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	391
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	392	lemma nn_integral_completion: "nn_integral (completion M) f = nn_integral M f"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	393	unfolding nn_integral_def
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	394	proof (safe intro!: SUP_eq)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	395	fix s assume s: "simple_function (completion M) s" and "s \<le> f"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	396	then obtain s' where s': "simple_function M s'" "AE x in M. s x = s' x"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	397	by (auto dest: completion_ex_simple_function)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	398	then obtain N where N: "N \<in> null_sets M" "{x\<in>space M. s x \<noteq> s' x} \<subseteq> N"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	399	by (auto elim!: AE_E)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	400	then have ae_N: "AE x in M. (s x \<noteq> s' x \<longrightarrow> x \<in> N) \<and> x \<notin> N"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	401	by (auto dest: AE_not_in)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	402	define s'' where "s'' x = (if x \<in> N then 0 else s x)" for x
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	403	then have ae_s_eq_s'': "AE x in completion M. s x = s'' x"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	404	using s' ae_N by (intro AE_completion) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	405	have s'': "simple_function M s''"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	406	proof (subst simple_function_cong)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	407	show "t \<in> space M \<Longrightarrow> s'' t = (if t \<in> N then 0 else s' t)" for t
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	408	using N by (auto simp: s''_def dest: sets.sets_into_space)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	409	show "simple_function M (\<lambda>t. if t \<in> N then 0 else s' t)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	410	unfolding s''_def[abs_def] using N by (auto intro!: simple_function_If s')
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	411	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	412
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	413	show "\<exists>j\<in>{g. simple_function M g \<and> g \<le> f}. integral\<^sup>S (completion M) s \<le> integral\<^sup>S M j"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	414	proof (safe intro!: bexI[of _ s''])
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	415	have "integral\<^sup>S (completion M) s = integral\<^sup>S (completion M) s''"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	416	by (intro simple_integral_cong_AE s simple_function_completion s'' ae_s_eq_s'')
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	417	then show "integral\<^sup>S (completion M) s \<le> integral\<^sup>S M s''"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	418	using s'' by (simp add: simple_integral_completion)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	419	from \<open>s \<le> f\<close> show "s'' \<le> f"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	420	unfolding s''_def le_fun_def by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	421	qed fact
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	422	next
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	423	fix s assume "simple_function M s" "s \<le> f"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	424	then show "\<exists>j\<in>{g. simple_function (completion M) g \<and> g \<le> f}. integral\<^sup>S M s \<le> integral\<^sup>S (completion M) j"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	425	by (intro bexI[of _ s]) (auto simp: simple_integral_completion simple_function_completion)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	426	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	427
63958 02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	428	lemma integrable_completion:
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	429	fixes f :: "'a \<Rightarrow> 'b::{banach, second_countable_topology}"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	430	shows "f \<in> M \<rightarrow>\<^sub>M borel \<Longrightarrow> integrable (completion M) f \<longleftrightarrow> integrable M f"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	431	by (rule integrable_subalgebra[symmetric]) auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	432
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	433	lemma integral_completion:
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	434	fixes f :: "'a \<Rightarrow> 'b::{banach, second_countable_topology}"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	435	assumes f: "f \<in> M \<rightarrow>\<^sub>M borel" shows "integral\<^sup>L (completion M) f = integral\<^sup>L M f"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	436	by (rule integral_subalgebra[symmetric]) (auto intro: f)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	437
63940 0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	438	locale semifinite_measure =
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	439	fixes M :: "'a measure"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	440	assumes semifinite:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	441	"\<And>A. A \<in> sets M \<Longrightarrow> emeasure M A = \<infinity> \<Longrightarrow> \<exists>B\<in>sets M. B \<subseteq> A \<and> emeasure M B < \<infinity>"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	442
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	443	locale locally_determined_measure = semifinite_measure +
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	444	assumes locally_determined:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	445	"\<And>A. A \<subseteq> space M \<Longrightarrow> (\<And>B. B \<in> sets M \<Longrightarrow> emeasure M B < \<infinity> \<Longrightarrow> A \<inter> B \<in> sets M) \<Longrightarrow> A \<in> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	446
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	447	locale cld_measure = complete_measure M + locally_determined_measure M for M :: "'a measure"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	448
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	449	definition outer_measure_of :: "'a measure \<Rightarrow> 'a set \<Rightarrow> ennreal"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	450	where "outer_measure_of M A = (INF B : {B\<in>sets M. A \<subseteq> B}. emeasure M B)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	451
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	452	lemma outer_measure_of_eq[simp]: "A \<in> sets M \<Longrightarrow> outer_measure_of M A = emeasure M A"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	453	by (auto simp: outer_measure_of_def intro!: INF_eqI emeasure_mono)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	454
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	455	lemma outer_measure_of_mono: "A \<subseteq> B \<Longrightarrow> outer_measure_of M A \<le> outer_measure_of M B"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	456	unfolding outer_measure_of_def by (intro INF_superset_mono) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	457
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	458	lemma outer_measure_of_attain:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	459	assumes "A \<subseteq> space M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	460	shows "\<exists>E\<in>sets M. A \<subseteq> E \<and> outer_measure_of M A = emeasure M E"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	461	proof -
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	462	have "emeasure M ` {B \<in> sets M. A \<subseteq> B} \<noteq> {}"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	463	using \<open>A \<subseteq> space M\<close> by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	464	from ennreal_Inf_countable_INF[OF this]
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	465	obtain f
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	466	where f: "range f \<subseteq> emeasure M ` {B \<in> sets M. A \<subseteq> B}" "decseq f"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	467	and "outer_measure_of M A = (INF i. f i)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	468	unfolding outer_measure_of_def by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	469	have "\<exists>E. \<forall>n. (E n \<in> sets M \<and> A \<subseteq> E n \<and> emeasure M (E n) \<le> f n) \<and> E (Suc n) \<subseteq> E n"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	470	proof (rule dependent_nat_choice)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	471	show "\<exists>x. x \<in> sets M \<and> A \<subseteq> x \<and> emeasure M x \<le> f 0"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	472	using f(1) by (fastforce simp: image_subset_iff image_iff intro: eq_refl[OF sym])
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	473	next
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	474	fix E n assume "E \<in> sets M \<and> A \<subseteq> E \<and> emeasure M E \<le> f n"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	475	moreover obtain F where "F \<in> sets M" "A \<subseteq> F" "f (Suc n) = emeasure M F"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	476	using f(1) by (auto simp: image_subset_iff image_iff)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	477	ultimately show "\<exists>y. (y \<in> sets M \<and> A \<subseteq> y \<and> emeasure M y \<le> f (Suc n)) \<and> y \<subseteq> E"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	478	by (auto intro!: exI[of _ "F \<inter> E"] emeasure_mono)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	479	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	480	then obtain E
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	481	where [simp]: "\<And>n. E n \<in> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	482	and "\<And>n. A \<subseteq> E n"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	483	and le_f: "\<And>n. emeasure M (E n) \<le> f n"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	484	and "decseq E"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	485	by (auto simp: decseq_Suc_iff)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	486	show ?thesis
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	487	proof cases
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	488	assume fin: "\<exists>i. emeasure M (E i) < \<infinity>"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	489	show ?thesis
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	490	proof (intro bexI[of _ "\<Inter>i. E i"] conjI)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	491	show "A \<subseteq> (\<Inter>i. E i)" "(\<Inter>i. E i) \<in> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	492	using \<open>\<And>n. A \<subseteq> E n\<close> by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	493
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	494	have " (INF i. emeasure M (E i)) \<le> outer_measure_of M A"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	495	unfolding \<open>outer_measure_of M A = (INF n. f n)\<close>
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	496	by (intro INF_superset_mono le_f) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	497	moreover have "outer_measure_of M A \<le> (INF i. outer_measure_of M (E i))"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	498	by (intro INF_greatest outer_measure_of_mono \<open>\<And>n. A \<subseteq> E n\<close>)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	499	ultimately have "outer_measure_of M A = (INF i. emeasure M (E i))"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	500	by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	501	also have "\<dots> = emeasure M (\<Inter>i. E i)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	502	using fin by (intro INF_emeasure_decseq' \<open>decseq E\<close>) (auto simp: less_top)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	503	finally show "outer_measure_of M A = emeasure M (\<Inter>i. E i)" .
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	504	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	505	next
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	506	assume "\<nexists>i. emeasure M (E i) < \<infinity>"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	507	then have "f n = \<infinity>" for n
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	508	using le_f by (auto simp: not_less top_unique)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	509	moreover have "\<exists>E\<in>sets M. A \<subseteq> E \<and> f 0 = emeasure M E"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	510	using f by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	511	ultimately show ?thesis
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	512	unfolding \<open>outer_measure_of M A = (INF n. f n)\<close> by simp
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	513	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	514	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	515
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	516	lemma SUP_outer_measure_of_incseq:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	517	assumes A: "\<And>n. A n \<subseteq> space M" and "incseq A"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	518	shows "(SUP n. outer_measure_of M (A n)) = outer_measure_of M (\<Union>i. A i)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	519	proof (rule antisym)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	520	obtain E
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	521	where E: "\<And>n. E n \<in> sets M" "\<And>n. A n \<subseteq> E n" "\<And>n. outer_measure_of M (A n) = emeasure M (E n)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	522	using outer_measure_of_attain[OF A] by metis
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	523
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	524	define F where "F n = (\<Inter>i\<in>{n ..}. E i)" for n
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	525	with E have F: "incseq F" "\<And>n. F n \<in> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	526	by (auto simp: incseq_def)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	527	have "A n \<subseteq> F n" for n
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	528	using incseqD[OF \<open>incseq A\<close>, of n] \<open>\<And>n. A n \<subseteq> E n\<close> by (auto simp: F_def)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	529
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	530	have eq: "outer_measure_of M (A n) = outer_measure_of M (F n)" for n
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	531	proof (intro antisym)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	532	have "outer_measure_of M (F n) \<le> outer_measure_of M (E n)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	533	by (intro outer_measure_of_mono) (auto simp add: F_def)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	534	with E show "outer_measure_of M (F n) \<le> outer_measure_of M (A n)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	535	by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	536	show "outer_measure_of M (A n) \<le> outer_measure_of M (F n)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	537	by (intro outer_measure_of_mono \<open>A n \<subseteq> F n\<close>)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	538	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	539
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	540	have "outer_measure_of M (\<Union>n. A n) \<le> outer_measure_of M (\<Union>n. F n)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	541	using \<open>\<And>n. A n \<subseteq> F n\<close> by (intro outer_measure_of_mono) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	542	also have "\<dots> = (SUP n. emeasure M (F n))"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	543	using F by (simp add: SUP_emeasure_incseq subset_eq)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	544	finally show "outer_measure_of M (\<Union>n. A n) \<le> (SUP n. outer_measure_of M (A n))"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	545	by (simp add: eq F)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	546	qed (auto intro: SUP_least outer_measure_of_mono)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	547
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	548	definition measurable_envelope :: "'a measure \<Rightarrow> 'a set \<Rightarrow> 'a set \<Rightarrow> bool"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	549	where "measurable_envelope M A E \<longleftrightarrow>
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	550	(A \<subseteq> E \<and> E \<in> sets M \<and> (\<forall>F\<in>sets M. emeasure M (F \<inter> E) = outer_measure_of M (F \<inter> A)))"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	551
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	552	lemma measurable_envelopeD:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	553	assumes "measurable_envelope M A E"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	554	shows "A \<subseteq> E"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	555	and "E \<in> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	556	and "\<And>F. F \<in> sets M \<Longrightarrow> emeasure M (F \<inter> E) = outer_measure_of M (F \<inter> A)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	557	and "A \<subseteq> space M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	558	using assms sets.sets_into_space[of E] by (auto simp: measurable_envelope_def)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	559
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	560	lemma measurable_envelopeD1:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	561	assumes E: "measurable_envelope M A E" and F: "F \<in> sets M" "F \<subseteq> E - A"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	562	shows "emeasure M F = 0"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	563	proof -
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	564	have "emeasure M F = emeasure M (F \<inter> E)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	565	using F by (intro arg_cong2[where f=emeasure]) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	566	also have "\<dots> = outer_measure_of M (F \<inter> A)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	567	using measurable_envelopeD[OF E] \<open>F \<in> sets M\<close> by (auto simp: measurable_envelope_def)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	568	also have "\<dots> = outer_measure_of M {}"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	569	using \<open>F \<subseteq> E - A\<close> by (intro arg_cong2[where f=outer_measure_of]) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	570	finally show "emeasure M F = 0"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	571	by simp
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	572	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	573
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	574	lemma measurable_envelope_eq1:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	575	assumes "A \<subseteq> E" "E \<in> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	576	shows "measurable_envelope M A E \<longleftrightarrow> (\<forall>F\<in>sets M. F \<subseteq> E - A \<longrightarrow> emeasure M F = 0)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	577	proof safe
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	578	assume *: "\<forall>F\<in>sets M. F \<subseteq> E - A \<longrightarrow> emeasure M F = 0"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	579	show "measurable_envelope M A E"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	580	unfolding measurable_envelope_def
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	581	proof (rule ccontr, auto simp add: \<open>E \<in> sets M\<close> \<open>A \<subseteq> E\<close>)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	582	fix F assume "F \<in> sets M" "emeasure M (F \<inter> E) \<noteq> outer_measure_of M (F \<inter> A)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	583	then have "outer_measure_of M (F \<inter> A) < emeasure M (F \<inter> E)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	584	using outer_measure_of_mono[of "F \<inter> A" "F \<inter> E" M] \<open>A \<subseteq> E\<close> \<open>E \<in> sets M\<close> by (auto simp: less_le)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	585	then obtain G where G: "G \<in> sets M" "F \<inter> A \<subseteq> G" and less: "emeasure M G < emeasure M (E \<inter> F)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	586	unfolding outer_measure_of_def INF_less_iff by (auto simp: ac_simps)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	587	have le: "emeasure M (G \<inter> E \<inter> F) \<le> emeasure M G"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	588	using \<open>E \<in> sets M\<close> \<open>G \<in> sets M\<close> \<open>F \<in> sets M\<close> by (auto intro!: emeasure_mono)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	589
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	590	from G have "E \<inter> F - G \<in> sets M" "E \<inter> F - G \<subseteq> E - A"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	591	using \<open>F \<in> sets M\<close> \<open>E \<in> sets M\<close> by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	592	with * have "0 = emeasure M (E \<inter> F - G)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	593	by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	594	also have "E \<inter> F - G = E \<inter> F - (G \<inter> E \<inter> F)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	595	by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	596	also have "emeasure M (E \<inter> F - (G \<inter> E \<inter> F)) = emeasure M (E \<inter> F) - emeasure M (G \<inter> E \<inter> F)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	597	using \<open>E \<in> sets M\<close> \<open>F \<in> sets M\<close> le less G by (intro emeasure_Diff) (auto simp: top_unique)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	598	also have "\<dots> > 0"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	599	using le less by (intro diff_gr0_ennreal) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	600	finally show False by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	601	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	602	qed (rule measurable_envelopeD1)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	603
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	604	lemma measurable_envelopeD2:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	605	assumes E: "measurable_envelope M A E" shows "emeasure M E = outer_measure_of M A"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	606	proof -
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	607	from \<open>measurable_envelope M A E\<close> have "emeasure M (E \<inter> E) = outer_measure_of M (E \<inter> A)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	608	by (auto simp: measurable_envelope_def)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	609	with measurable_envelopeD[OF E] show "emeasure M E = outer_measure_of M A"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	610	by (auto simp: Int_absorb1)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	611	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	612
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	613	lemma measurable_envelope_eq2:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	614	assumes "A \<subseteq> E" "E \<in> sets M" "emeasure M E < \<infinity>"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	615	shows "measurable_envelope M A E \<longleftrightarrow> (emeasure M E = outer_measure_of M A)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	616	proof safe
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	617	assume *: "emeasure M E = outer_measure_of M A"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	618	show "measurable_envelope M A E"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	619	unfolding measurable_envelope_eq1[OF \<open>A \<subseteq> E\<close> \<open>E \<in> sets M\<close>]
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	620	proof (intro conjI ballI impI assms)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	621	fix F assume F: "F \<in> sets M" "F \<subseteq> E - A"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	622	with \<open>E \<in> sets M\<close> have le: "emeasure M F \<le> emeasure M E"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	623	by (intro emeasure_mono) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	624	from F \<open>A \<subseteq> E\<close> have "outer_measure_of M A \<le> outer_measure_of M (E - F)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	625	by (intro outer_measure_of_mono) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	626	then have "emeasure M E - 0 \<le> emeasure M (E - F)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	627	using * \<open>E \<in> sets M\<close> \<open>F \<in> sets M\<close> by simp
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	628	also have "\<dots> = emeasure M E - emeasure M F"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	629	using \<open>E \<in> sets M\<close> \<open>emeasure M E < \<infinity>\<close> F le by (intro emeasure_Diff) (auto simp: top_unique)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	630	finally show "emeasure M F = 0"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	631	using ennreal_mono_minus_cancel[of "emeasure M E" 0 "emeasure M F"] le assms by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	632	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	633	qed (auto intro: measurable_envelopeD2)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	634
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	635	lemma measurable_envelopeI_countable:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	636	fixes A :: "nat \<Rightarrow> 'a set"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	637	assumes E: "\<And>n. measurable_envelope M (A n) (E n)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	638	shows "measurable_envelope M (\<Union>n. A n) (\<Union>n. E n)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	639	proof (subst measurable_envelope_eq1)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	640	show "(\<Union>n. A n) \<subseteq> (\<Union>n. E n)" "(\<Union>n. E n) \<in> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	641	using measurable_envelopeD(1,2)[OF E] by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	642	show "\<forall>F\<in>sets M. F \<subseteq> (\<Union>n. E n) - (\<Union>n. A n) \<longrightarrow> emeasure M F = 0"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	643	proof safe
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	644	fix F assume F: "F \<in> sets M" "F \<subseteq> (\<Union>n. E n) - (\<Union>n. A n)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	645	then have "F \<inter> E n \<in> sets M" "F \<inter> E n \<subseteq> E n - A n" "F \<subseteq> (\<Union>n. E n)" for n
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	646	using measurable_envelopeD(1,2)[OF E] by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	647	then have "emeasure M (\<Union>n. F \<inter> E n) = 0"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	648	by (intro emeasure_UN_eq_0 measurable_envelopeD1[OF E]) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	649	then show "emeasure M F = 0"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	650	using \<open>F \<subseteq> (\<Union>n. E n)\<close> by (auto simp: Int_absorb2)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	651	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	652	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	653
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	654	lemma measurable_envelopeI_countable_cover:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	655	fixes A and C :: "nat \<Rightarrow> 'a set"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	656	assumes C: "A \<subseteq> (\<Union>n. C n)" "\<And>n. C n \<in> sets M" "\<And>n. emeasure M (C n) < \<infinity>"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	657	shows "\<exists>E\<subseteq>(\<Union>n. C n). measurable_envelope M A E"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	658	proof -
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	659	have "A \<inter> C n \<subseteq> space M" for n
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	660	using \<open>C n \<in> sets M\<close> by (auto dest: sets.sets_into_space)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	661	then have "\<forall>n. \<exists>E\<in>sets M. A \<inter> C n \<subseteq> E \<and> outer_measure_of M (A \<inter> C n) = emeasure M E"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	662	using outer_measure_of_attain[of "A \<inter> C n" M for n] by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	663	then obtain E
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	664	where E: "\<And>n. E n \<in> sets M" "\<And>n. A \<inter> C n \<subseteq> E n"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	665	and eq: "\<And>n. outer_measure_of M (A \<inter> C n) = emeasure M (E n)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	666	by metis
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	667
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	668	have "outer_measure_of M (A \<inter> C n) \<le> outer_measure_of M (E n \<inter> C n)" for n
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	669	using E by (intro outer_measure_of_mono) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	670	moreover have "outer_measure_of M (E n \<inter> C n) \<le> outer_measure_of M (E n)" for n
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	671	by (intro outer_measure_of_mono) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	672	ultimately have eq: "outer_measure_of M (A \<inter> C n) = emeasure M (E n \<inter> C n)" for n
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	673	using E C by (intro antisym) (auto simp: eq)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	674
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	675	{ fix n
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	676	have "outer_measure_of M (A \<inter> C n) \<le> outer_measure_of M (C n)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	677	by (intro outer_measure_of_mono) simp
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	678	also have "\<dots> < \<infinity>"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	679	using assms by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	680	finally have "emeasure M (E n \<inter> C n) < \<infinity>"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	681	using eq by simp }
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	682	then have "measurable_envelope M (\<Union>n. A \<inter> C n) (\<Union>n. E n \<inter> C n)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	683	using E C by (intro measurable_envelopeI_countable measurable_envelope_eq2[THEN iffD2]) (auto simp: eq)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	684	with \<open>A \<subseteq> (\<Union>n. C n)\<close> show ?thesis
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	685	by (intro exI[of _ "(\<Union>n. E n \<inter> C n)"]) (auto simp add: Int_absorb2)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	686	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	687
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	688	lemma (in complete_measure) complete_sets_sandwich:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	689	assumes [measurable]: "A \<in> sets M" "C \<in> sets M" and subset: "A \<subseteq> B" "B \<subseteq> C"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	690	and measure: "emeasure M A = emeasure M C" "emeasure M A < \<infinity>"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	691	shows "B \<in> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	692	proof -
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	693	have "B - A \<in> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	694	proof (rule complete)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	695	show "B - A \<subseteq> C - A"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	696	using subset by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	697	show "C - A \<in> null_sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	698	using measure subset by(simp add: emeasure_Diff null_setsI)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	699	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	700	then have "A \<union> (B - A) \<in> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	701	by measurable
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	702	also have "A \<union> (B - A) = B"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	703	using \<open>A \<subseteq> B\<close> by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	704	finally show ?thesis .
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	705	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	706
63958 02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	707	lemma (in complete_measure) complete_sets_sandwich_fmeasurable:
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	708	assumes [measurable]: "A \<in> fmeasurable M" "C \<in> fmeasurable M" and subset: "A \<subseteq> B" "B \<subseteq> C"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	709	and measure: "measure M A = measure M C"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	710	shows "B \<in> fmeasurable M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	711	proof (rule fmeasurableI2)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	712	show "B \<subseteq> C" "C \<in> fmeasurable M" by fact+
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	713	show "B \<in> sets M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	714	proof (rule complete_sets_sandwich)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	715	show "A \<in> sets M" "C \<in> sets M" "A \<subseteq> B" "B \<subseteq> C"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	716	using assms by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	717	show "emeasure M A < \<infinity>"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	718	using \<open>A \<in> fmeasurable M\<close> by (auto simp: fmeasurable_def)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	719	show "emeasure M A = emeasure M C"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	720	using assms by (simp add: emeasure_eq_measure2)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	721	qed
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	722	qed
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	723
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	724	lemma AE_completion_iff: "(AE x in completion M. P x) \<longleftrightarrow> (AE x in M. P x)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	725	proof
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	726	assume "AE x in completion M. P x"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	727	then obtain N where "N \<in> null_sets (completion M)" and P: "{x\<in>space M. \<not> P x} \<subseteq> N"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	728	unfolding eventually_ae_filter by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	729	then obtain N' where N': "N' \<in> null_sets M" and "N \<subseteq> N'"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	730	unfolding null_sets_completion_iff2 by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	731	from P \<open>N \<subseteq> N'\<close> have "{x\<in>space M. \<not> P x} \<subseteq> N'"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	732	by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	733	with N' show "AE x in M. P x"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	734	unfolding eventually_ae_filter by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	735	qed (rule AE_completion)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	736
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	737	lemma null_part_null_sets: "S \<in> completion M \<Longrightarrow> null_part M S \<in> null_sets (completion M)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	738	by (auto dest!: null_part intro: null_sets_completionI null_sets_completion_subset)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	739
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	740	lemma AE_notin_null_part: "S \<in> completion M \<Longrightarrow> (AE x in M. x \<notin> null_part M S)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	741	by (auto dest!: null_part_null_sets AE_not_in simp: AE_completion_iff)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	742
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	743	lemma completion_upper:
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	744	assumes A: "A \<in> sets (completion M)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	745	shows "\<exists>A'\<in>sets M. A \<subseteq> A' \<and> emeasure (completion M) A = emeasure M A'"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	746	proof -
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	747	from AE_notin_null_part[OF A] obtain N where N: "N \<in> null_sets M" "null_part M A \<subseteq> N"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	748	unfolding eventually_ae_filter using null_part_null_sets[OF A, THEN null_setsD2, THEN sets.sets_into_space] by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	749	show ?thesis
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	750	proof (intro bexI conjI)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	751	show "A \<subseteq> main_part M A \<union> N"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	752	using \<open>null_part M A \<subseteq> N\<close> by (subst main_part_null_part_Un[symmetric, OF A]) auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	753	show "emeasure (completion M) A = emeasure M (main_part M A \<union> N)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	754	using A \<open>N \<in> null_sets M\<close> by (simp add: emeasure_Un_null_set)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	755	qed (use A N in auto)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	756	qed
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	757
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	758	lemma AE_in_main_part:
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	759	assumes A: "A \<in> completion M" shows "AE x in M. x \<in> main_part M A \<longleftrightarrow> x \<in> A"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	760	using AE_notin_null_part[OF A]
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	761	by (subst (2) main_part_null_part_Un[symmetric, OF A]) auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	762
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	763	lemma completion_density_eq:
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	764	assumes ae: "AE x in M. 0 < f x" and [measurable]: "f \<in> M \<rightarrow>\<^sub>M borel"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	765	shows "completion (density M f) = density (completion M) f"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	766	proof (intro measure_eqI)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	767	have "N' \<in> sets M \<and> (AE x\<in>N' in M. f x = 0) \<longleftrightarrow> N' \<in> null_sets M" for N'
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	768	proof safe
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	769	assume N': "N' \<in> sets M" and ae_N': "AE x\<in>N' in M. f x = 0"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	770	from ae_N' ae have "AE x in M. x \<notin> N'"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	771	by eventually_elim auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	772	then show "N' \<in> null_sets M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	773	using N' by (simp add: AE_iff_null_sets)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	774	next
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	775	assume N': "N' \<in> null_sets M" then show "N' \<in> sets M" "AE x\<in>N' in M. f x = 0"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	776	using ae AE_not_in[OF N'] by (auto simp: less_le)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	777	qed
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	778	then show sets_eq: "sets (completion (density M f)) = sets (density (completion M) f)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	779	by (simp add: sets_completion null_sets_density_iff)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	780
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	781	fix A assume A: \<open>A \<in> completion (density M f)\<close>
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	782	moreover
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	783	have "A \<in> completion M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	784	using A unfolding sets_eq by simp
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	785	moreover
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	786	have "main_part (density M f) A \<in> M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	787	using A main_part_sets[of A "density M f"] unfolding sets_density sets_eq by simp
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	788	moreover have "AE x in M. x \<in> main_part (density M f) A \<longleftrightarrow> x \<in> A"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	789	using AE_in_main_part[OF \<open>A \<in> completion (density M f)\<close>] ae by (auto simp add: AE_density)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	790	ultimately show "emeasure (completion (density M f)) A = emeasure (density (completion M) f) A"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	791	by (auto simp add: emeasure_density measurable_completion nn_integral_completion intro!: nn_integral_cong_AE)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	792	qed
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	793
64284 f3b905b2eee2 HOL-Analysis: more theorems from Sébastien Gouëzel's Ergodic_Theory hoelzl parents: 63968 diff changeset	794	lemma null_sets_subset: "B \<in> null_sets M \<Longrightarrow> A \<in> sets M \<Longrightarrow> A \<subseteq> B \<Longrightarrow> A \<in> null_sets M"
63958 02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	795	using emeasure_mono[of A B M] by (simp add: null_sets_def)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	796
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	797	lemma (in complete_measure) complete2: "A \<subseteq> B \<Longrightarrow> B \<in> null_sets M \<Longrightarrow> A \<in> null_sets M"
64284 f3b905b2eee2 HOL-Analysis: more theorems from Sébastien Gouëzel's Ergodic_Theory hoelzl parents: 63968 diff changeset	798	using complete[of A B] null_sets_subset[of B M A] by simp
63958 02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	799
63959 f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	800	lemma (in complete_measure) AE_iff_null_sets: "(AE x in M. P x) \<longleftrightarrow> {x\<in>space M. \<not> P x} \<in> null_sets M"
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	801	unfolding eventually_ae_filter by (auto intro: complete2)
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	802
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	803	lemma (in complete_measure) null_sets_iff_AE: "A \<in> null_sets M \<longleftrightarrow> ((AE x in M. x \<notin> A) \<and> A \<subseteq> space M)"
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	804	unfolding AE_iff_null_sets by (auto cong: rev_conj_cong dest: sets.sets_into_space simp: subset_eq)
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	805
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	806	lemma (in complete_measure) in_sets_AE:
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	807	assumes ae: "AE x in M. x \<in> A \<longleftrightarrow> x \<in> B" and A: "A \<in> sets M" and B: "B \<subseteq> space M"
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	808	shows "B \<in> sets M"
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	809	proof -
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	810	have "(AE x in M. x \<notin> B - A \<and> x \<notin> A - B)"
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	811	using ae by eventually_elim auto
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	812	then have "B - A \<in> null_sets M" "A - B \<in> null_sets M"
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	813	using A B unfolding null_sets_iff_AE by (auto dest: sets.sets_into_space)
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	814	then have "A \<union> (B - A) - (A - B) \<in> sets M"
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	815	using A by blast
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	816	also have "A \<union> (B - A) - (A - B) = B"
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	817	by auto
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	818	finally show "B \<in> sets M" .
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	819	qed
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	820
63958 02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	821	lemma (in complete_measure) vimage_null_part_null_sets:
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	822	assumes f: "f \<in> M \<rightarrow>\<^sub>M N" and eq: "null_sets N \<subseteq> null_sets (distr M N f)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	823	and A: "A \<in> completion N"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	824	shows "f -` null_part N A \<inter> space M \<in> null_sets M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	825	proof -
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	826	obtain N' where "N' \<in> null_sets N" "null_part N A \<subseteq> N'"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	827	using null_part[OF A] by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	828	then have N': "N' \<in> null_sets (distr M N f)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	829	using eq by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	830	show ?thesis
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	831	proof (rule complete2)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	832	show "f -` null_part N A \<inter> space M \<subseteq> f -` N' \<inter> space M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	833	using \<open>null_part N A \<subseteq> N'\<close> by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	834	show "f -` N' \<inter> space M \<in> null_sets M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	835	using f N' by (auto simp: null_sets_def emeasure_distr)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	836	qed
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	837	qed
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	838
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	839	lemma (in complete_measure) vimage_null_part_sets:
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	840	"f \<in> M \<rightarrow>\<^sub>M N \<Longrightarrow> null_sets N \<subseteq> null_sets (distr M N f) \<Longrightarrow> A \<in> completion N \<Longrightarrow>
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	841	f -` null_part N A \<inter> space M \<in> sets M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	842	using vimage_null_part_null_sets[of f N A] by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	843
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	844	lemma (in complete_measure) measurable_completion2:
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	845	assumes f: "f \<in> M \<rightarrow>\<^sub>M N" and null_sets: "null_sets N \<subseteq> null_sets (distr M N f)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	846	shows "f \<in> M \<rightarrow>\<^sub>M completion N"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	847	proof (rule measurableI)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	848	show "x \<in> space M \<Longrightarrow> f x \<in> space (completion N)" for x
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	849	using f[THEN measurable_space] by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	850	fix A assume A: "A \<in> sets (completion N)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	851	have "f -` A \<inter> space M = (f -` main_part N A \<inter> space M) \<union> (f -` null_part N A \<inter> space M)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	852	using main_part_null_part_Un[OF A] by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	853	then show "f -` A \<inter> space M \<in> sets M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	854	using f A null_sets by (auto intro: vimage_null_part_sets measurable_sets)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	855	qed
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	856
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	857	lemma (in complete_measure) completion_distr_eq:
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	858	assumes X: "X \<in> M \<rightarrow>\<^sub>M N" and null_sets: "null_sets (distr M N X) = null_sets N"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	859	shows "completion (distr M N X) = distr M (completion N) X"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	860	proof (rule measure_eqI)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	861	show eq: "sets (completion (distr M N X)) = sets (distr M (completion N) X)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	862	by (simp add: sets_completion null_sets)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	863
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	864	fix A assume A: "A \<in> completion (distr M N X)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	865	moreover have A': "A \<in> completion N"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	866	using A by (simp add: eq)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	867	moreover have "main_part (distr M N X) A \<in> sets N"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	868	using main_part_sets[OF A] by simp
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	869	moreover have "X -` A \<inter> space M = (X -` main_part (distr M N X) A \<inter> space M) \<union> (X -` null_part (distr M N X) A \<inter> space M)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	870	using main_part_null_part_Un[OF A] by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	871	moreover have "X -` null_part (distr M N X) A \<inter> space M \<in> null_sets M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	872	using X A by (intro vimage_null_part_null_sets) (auto cong: distr_cong)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	873	ultimately show "emeasure (completion (distr M N X)) A = emeasure (distr M (completion N) X) A"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	874	using X by (auto simp: emeasure_distr measurable_completion null_sets measurable_completion2
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	875	intro!: emeasure_Un_null_set[symmetric])
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	876	qed
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	877
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	878	lemma distr_completion: "X \<in> M \<rightarrow>\<^sub>M N \<Longrightarrow> distr (completion M) N X = distr M N X"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	879	by (intro measure_eqI) (auto simp: emeasure_distr measurable_completion)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	880
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	881	proposition (in complete_measure) fmeasurable_inner_outer:
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	882	"S \<in> fmeasurable M \<longleftrightarrow>
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	883	(\<forall>e>0. \<exists>T\<in>fmeasurable M. \<exists>U\<in>fmeasurable M. T \<subseteq> S \<and> S \<subseteq> U \<and> \<bar>measure M T - measure M U\<bar> < e)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	884	(is "_ \<longleftrightarrow> ?approx")
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	885	proof safe
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	886	let ?\<mu> = "measure M" let ?D = "\<lambda>T U . \<bar>?\<mu> T - ?\<mu> U\<bar>"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	887	assume ?approx
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	888	have "\<exists>A. \<forall>n. (fst (A n) \<in> fmeasurable M \<and> snd (A n) \<in> fmeasurable M \<and> fst (A n) \<subseteq> S \<and> S \<subseteq> snd (A n) \<and>
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	889	?D (fst (A n)) (snd (A n)) < 1/Suc n) \<and> (fst (A n) \<subseteq> fst (A (Suc n)) \<and> snd (A (Suc n)) \<subseteq> snd (A n))"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	890	(is "\<exists>A. \<forall>n. ?P n (A n) \<and> ?Q (A n) (A (Suc n))")
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	891	proof (intro dependent_nat_choice)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	892	show "\<exists>A. ?P 0 A"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	893	using \<open>?approx\<close>[THEN spec, of 1] by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	894	next
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	895	fix A n assume "?P n A"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	896	moreover
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	897	from \<open>?approx\<close>[THEN spec, of "1/Suc (Suc n)"]
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	898	obtain T U where *: "T \<in> fmeasurable M" "U \<in> fmeasurable M" "T \<subseteq> S" "S \<subseteq> U" "?D T U < 1 / Suc (Suc n)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	899	by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	900	ultimately have "?\<mu> T \<le> ?\<mu> (T \<union> fst A)" "?\<mu> (U \<inter> snd A) \<le> ?\<mu> U"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	901	"?\<mu> T \<le> ?\<mu> U" "?\<mu> (T \<union> fst A) \<le> ?\<mu> (U \<inter> snd A)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	902	by (auto intro!: measure_mono_fmeasurable)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	903	then have "?D (T \<union> fst A) (U \<inter> snd A) \<le> ?D T U"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	904	by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	905	also have "?D T U < 1/Suc (Suc n)" by fact
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	906	finally show "\<exists>B. ?P (Suc n) B \<and> ?Q A B"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	907	using \<open>?P n A\<close> *
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	908	by (intro exI[of _ "(T \<union> fst A, U \<inter> snd A)"] conjI) auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	909	qed
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	910	then obtain A
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	911	where lm: "\<And>n. fst (A n) \<in> fmeasurable M" "\<And>n. snd (A n) \<in> fmeasurable M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	912	and set_bound: "\<And>n. fst (A n) \<subseteq> S" "\<And>n. S \<subseteq> snd (A n)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	913	and mono: "\<And>n. fst (A n) \<subseteq> fst (A (Suc n))" "\<And>n. snd (A (Suc n)) \<subseteq> snd (A n)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	914	and bound: "\<And>n. ?D (fst (A n)) (snd (A n)) < 1/Suc n"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	915	by metis
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	916
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	917	have INT_sA: "(\<Inter>n. snd (A n)) \<in> fmeasurable M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	918	using lm by (intro fmeasurable_INT[of _ 0]) auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	919	have UN_fA: "(\<Union>n. fst (A n)) \<in> fmeasurable M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	920	using lm order_trans[OF set_bound(1) set_bound(2)[of 0]] by (intro fmeasurable_UN[of _ _ "snd (A 0)"]) auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	921
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	922	have "(\<lambda>n. ?\<mu> (fst (A n)) - ?\<mu> (snd (A n))) \<longlonglongrightarrow> 0"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	923	using bound
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	924	by (subst tendsto_rabs_zero_iff[symmetric])
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	925	(intro tendsto_sandwich[OF _ _ tendsto_const LIMSEQ_inverse_real_of_nat];
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	926	auto intro!: always_eventually less_imp_le simp: divide_inverse)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	927	moreover
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	928	have "(\<lambda>n. ?\<mu> (fst (A n)) - ?\<mu> (snd (A n))) \<longlonglongrightarrow> ?\<mu> (\<Union>n. fst (A n)) - ?\<mu> (\<Inter>n. snd (A n))"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	929	proof (intro tendsto_diff Lim_measure_incseq Lim_measure_decseq)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	930	show "range (\<lambda>i. fst (A i)) \<subseteq> sets M" "range (\<lambda>i. snd (A i)) \<subseteq> sets M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	931	"incseq (\<lambda>i. fst (A i))" "decseq (\<lambda>n. snd (A n))"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	932	using mono lm by (auto simp: incseq_Suc_iff decseq_Suc_iff intro!: measure_mono_fmeasurable)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	933	show "emeasure M (\<Union>x. fst (A x)) \<noteq> \<infinity>" "emeasure M (snd (A n)) \<noteq> \<infinity>" for n
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	934	using lm(2)[of n] UN_fA by (auto simp: fmeasurable_def)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	935	qed
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	936	ultimately have eq: "0 = ?\<mu> (\<Union>n. fst (A n)) - ?\<mu> (\<Inter>n. snd (A n))"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	937	by (rule LIMSEQ_unique)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	938
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	939	show "S \<in> fmeasurable M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	940	using UN_fA INT_sA
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	941	proof (rule complete_sets_sandwich_fmeasurable)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	942	show "(\<Union>n. fst (A n)) \<subseteq> S" "S \<subseteq> (\<Inter>n. snd (A n))"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	943	using set_bound by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	944	show "?\<mu> (\<Union>n. fst (A n)) = ?\<mu> (\<Inter>n. snd (A n))"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	945	using eq by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	946	qed
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	947	qed (auto intro!: bexI[of _ S])
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	948
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	949	lemma (in complete_measure) fmeasurable_measure_inner_outer:
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	950	"(S \<in> fmeasurable M \<and> m = measure M S) \<longleftrightarrow>
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	951	(\<forall>e>0. \<exists>T\<in>fmeasurable M. T \<subseteq> S \<and> m - e < measure M T) \<and>
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	952	(\<forall>e>0. \<exists>U\<in>fmeasurable M. S \<subseteq> U \<and> measure M U < m + e)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	953	(is "?lhs = ?rhs")
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	954	proof
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	955	assume RHS: ?rhs
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	956	then have T: "\<And>e. 0 < e \<longrightarrow> (\<exists>T\<in>fmeasurable M. T \<subseteq> S \<and> m - e < measure M T)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	957	and U: "\<And>e. 0 < e \<longrightarrow> (\<exists>U\<in>fmeasurable M. S \<subseteq> U \<and> measure M U < m + e)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	958	by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	959	have "S \<in> fmeasurable M"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	960	proof (subst fmeasurable_inner_outer, safe)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	961	fix e::real assume "0 < e"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	962	with RHS obtain T U where T: "T \<in> fmeasurable M" "T \<subseteq> S" "m - e/2 < measure M T"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	963	and U: "U \<in> fmeasurable M" "S \<subseteq> U" "measure M U < m + e/2"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	964	by (meson half_gt_zero)+
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	965	moreover have "measure M U - measure M T < (m + e/2) - (m - e/2)"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	966	by (intro diff_strict_mono) fact+
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	967	moreover have "measure M T \<le> measure M U"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	968	using T U by (intro measure_mono_fmeasurable) auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	969	ultimately show "\<exists>T\<in>fmeasurable M. \<exists>U\<in>fmeasurable M. T \<subseteq> S \<and> S \<subseteq> U \<and> \<bar>measure M T - measure M U\<bar> < e"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	970	apply (rule_tac bexI[OF _ \<open>T \<in> fmeasurable M\<close>])
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	971	apply (rule_tac bexI[OF _ \<open>U \<in> fmeasurable M\<close>])
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	972	by auto
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	973	qed
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	974	moreover have "m = measure M S"
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	975	using \<open>S \<in> fmeasurable M\<close> U[of "measure M S - m"] T[of "m - measure M S"]
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	976	by (cases m "measure M S" rule: linorder_cases)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	977	(auto simp: not_le[symmetric] measure_mono_fmeasurable)
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	978	ultimately show ?lhs
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	979	by simp
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	980	qed (auto intro!: bexI[of _ S])
02de4a58e210 HOL-Analysis: add measurable sets with finite measures, prove affine transformation rule for the Lebesgue measure hoelzl parents: 63941 diff changeset	981
63959 f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	982	lemma (in complete_measure) null_sets_outer:
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	983	"S \<in> null_sets M \<longleftrightarrow> (\<forall>e>0. \<exists>T\<in>fmeasurable M. S \<subseteq> T \<and> measure M T < e)"
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	984	proof -
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	985	have "S \<in> null_sets M \<longleftrightarrow> (S \<in> fmeasurable M \<and> 0 = measure M S)"
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	986	by (auto simp: null_sets_def emeasure_eq_measure2 intro: fmeasurableI) (simp add: measure_def)
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	987	also have "\<dots> = (\<forall>e>0. \<exists>T\<in>fmeasurable M. S \<subseteq> T \<and> measure M T < e)"
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	988	unfolding fmeasurable_measure_inner_outer by auto
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	989	finally show ?thesis .
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	990	qed
f77dca1abf1b HOL-Analysis: prove that a starlike set is negligible (based on HOL Light proof ported by L. C. Paulson) hoelzl parents: 63958 diff changeset	991
63940 0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	992	lemma (in cld_measure) notin_sets_outer_measure_of_cover:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	993	assumes E: "E \<subseteq> space M" "E \<notin> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	994	shows "\<exists>B\<in>sets M. 0 < emeasure M B \<and> emeasure M B < \<infinity> \<and>
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	995	outer_measure_of M (B \<inter> E) = emeasure M B \<and> outer_measure_of M (B - E) = emeasure M B"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	996	proof -
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	997	from locally_determined[OF \<open>E \<subseteq> space M\<close>] \<open>E \<notin> sets M\<close>
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	998	obtain F
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	999	where [measurable]: "F \<in> sets M" and "emeasure M F < \<infinity>" "E \<inter> F \<notin> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1000	by blast
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1001	then obtain H H'
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1002	where H: "measurable_envelope M (F \<inter> E) H" and H': "measurable_envelope M (F - E) H'"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1003	using measurable_envelopeI_countable_cover[of "F \<inter> E" "\<lambda>_. F" M]
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1004	measurable_envelopeI_countable_cover[of "F - E" "\<lambda>_. F" M]
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1005	by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1006	note measurable_envelopeD(2)[OF H', measurable] measurable_envelopeD(2)[OF H, measurable]
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1007
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1008	from measurable_envelopeD(1)[OF H'] measurable_envelopeD(1)[OF H]
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1009	have subset: "F - H' \<subseteq> F \<inter> E" "F \<inter> E \<subseteq> F \<inter> H"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1010	by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1011	moreover define G where "G = (F \<inter> H) - (F - H')"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1012	ultimately have G: "G = F \<inter> H \<inter> H'"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1013	by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1014	have "emeasure M (F \<inter> H) \<noteq> 0"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1015	proof
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1016	assume "emeasure M (F \<inter> H) = 0"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1017	then have "F \<inter> H \<in> null_sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1018	by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1019	with \<open>E \<inter> F \<notin> sets M\<close> show False
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1020	using complete[OF \<open>F \<inter> E \<subseteq> F \<inter> H\<close>] by (auto simp: Int_commute)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1021	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1022	moreover
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1023	have "emeasure M (F - H') \<noteq> emeasure M (F \<inter> H)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1024	proof
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1025	assume "emeasure M (F - H') = emeasure M (F \<inter> H)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1026	with \<open>E \<inter> F \<notin> sets M\<close> emeasure_mono[of "F \<inter> H" F M] \<open>emeasure M F < \<infinity>\<close>
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1027	have "F \<inter> E \<in> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1028	by (intro complete_sets_sandwich[OF _ _ subset]) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1029	with \<open>E \<inter> F \<notin> sets M\<close> show False
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1030	by (simp add: Int_commute)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1031	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1032	moreover have "emeasure M (F - H') \<le> emeasure M (F \<inter> H)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1033	using subset by (intro emeasure_mono) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1034	ultimately have "emeasure M G \<noteq> 0"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1035	unfolding G_def using subset
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1036	by (subst emeasure_Diff) (auto simp: top_unique diff_eq_0_iff_ennreal)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1037	show ?thesis
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1038	proof (intro bexI conjI)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1039	have "emeasure M G \<le> emeasure M F"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1040	unfolding G by (auto intro!: emeasure_mono)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1041	with \<open>emeasure M F < \<infinity>\<close> show "0 < emeasure M G" "emeasure M G < \<infinity>"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1042	using \<open>emeasure M G \<noteq> 0\<close> by (auto simp: zero_less_iff_neq_zero)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1043	show [measurable]: "G \<in> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1044	unfolding G by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1045
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1046	have "emeasure M G = outer_measure_of M (F \<inter> H' \<inter> (F \<inter> E))"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1047	using measurable_envelopeD(3)[OF H, of "F \<inter> H'"] unfolding G by (simp add: ac_simps)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1048	also have "\<dots> \<le> outer_measure_of M (G \<inter> E)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1049	using measurable_envelopeD(1)[OF H] by (intro outer_measure_of_mono) (auto simp: G)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1050	finally show "outer_measure_of M (G \<inter> E) = emeasure M G"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1051	using outer_measure_of_mono[of "G \<inter> E" G M] by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1052
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1053	have "emeasure M G = outer_measure_of M (F \<inter> H \<inter> (F - E))"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1054	using measurable_envelopeD(3)[OF H', of "F \<inter> H"] unfolding G by (simp add: ac_simps)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1055	also have "\<dots> \<le> outer_measure_of M (G - E)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1056	using measurable_envelopeD(1)[OF H'] by (intro outer_measure_of_mono) (auto simp: G)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1057	finally show "outer_measure_of M (G - E) = emeasure M G"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1058	using outer_measure_of_mono[of "G - E" G M] by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1059	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1060	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1061
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1062	text \<open>The following theorem is a specialization of D.H. Fremlin, Measure Theory vol 4I (413G). We
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1063	only show one direction and do not use a inner regular family $K$.\<close>
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1064
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1065	lemma (in cld_measure) borel_measurable_cld:
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1066	fixes f :: "'a \<Rightarrow> real"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1067	assumes "\<And>A a b. A \<in> sets M \<Longrightarrow> 0 < emeasure M A \<Longrightarrow> emeasure M A < \<infinity> \<Longrightarrow> a < b \<Longrightarrow>
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1068	min (outer_measure_of M {x\<in>A. f x \<le> a}) (outer_measure_of M {x\<in>A. b \<le> f x}) < emeasure M A"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1069	shows "f \<in> M \<rightarrow>\<^sub>M borel"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1070	proof (rule ccontr)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1071	let ?E = "\<lambda>a. {x\<in>space M. f x \<le> a}" and ?F = "\<lambda>a. {x\<in>space M. a \<le> f x}"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1072
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1073	assume "f \<notin> M \<rightarrow>\<^sub>M borel"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1074	then obtain a where "?E a \<notin> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1075	unfolding borel_measurable_iff_le by blast
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1076	from notin_sets_outer_measure_of_cover[OF _ this]
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1077	obtain K
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1078	where K: "K \<in> sets M" "0 < emeasure M K" "emeasure M K < \<infinity>"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1079	and eq1: "outer_measure_of M (K \<inter> ?E a) = emeasure M K"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1080	and eq2: "outer_measure_of M (K - ?E a) = emeasure M K"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1081	by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1082	then have me_K: "measurable_envelope M (K \<inter> ?E a) K"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1083	by (subst measurable_envelope_eq2) auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1084
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1085	define b where "b n = a + inverse (real (Suc n))" for n
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1086	have "(SUP n. outer_measure_of M (K \<inter> ?F (b n))) = outer_measure_of M (\<Union>n. K \<inter> ?F (b n))"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1087	proof (intro SUP_outer_measure_of_incseq)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1088	have "x \<le> y \<Longrightarrow> b y \<le> b x" for x y
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1089	by (auto simp: b_def field_simps)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1090	then show "incseq (\<lambda>n. K \<inter> {x \<in> space M. b n \<le> f x})"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1091	by (auto simp: incseq_def intro: order_trans)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1092	qed auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1093	also have "(\<Union>n. K \<inter> ?F (b n)) = K - ?E a"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1094	proof -
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1095	have "b \<longlonglongrightarrow> a"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1096	unfolding b_def by (rule LIMSEQ_inverse_real_of_nat_add)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1097	then have "\<forall>n. \<not> b n \<le> f x \<Longrightarrow> f x \<le> a" for x
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1098	by (rule LIMSEQ_le_const) (auto intro: less_imp_le simp: not_le)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1099	moreover have "\<not> b n \<le> a" for n
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1100	by (auto simp: b_def)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1101	ultimately show ?thesis
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1102	using \<open>K \<in> sets M\<close>[THEN sets.sets_into_space] by (auto simp: subset_eq intro: order_trans)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1103	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1104	finally have "0 < (SUP n. outer_measure_of M (K \<inter> ?F (b n)))"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1105	using K by (simp add: eq2)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1106	then obtain n where pos_b: "0 < outer_measure_of M (K \<inter> ?F (b n))" and "a < b n"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1107	unfolding less_SUP_iff by (auto simp: b_def)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1108	from measurable_envelopeI_countable_cover[of "K \<inter> ?F (b n)" "\<lambda>_. K" M] K
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1109	obtain K' where "K' \<subseteq> K" and me_K': "measurable_envelope M (K \<inter> ?F (b n)) K'"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1110	by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1111	then have K'_le_K: "emeasure M K' \<le> emeasure M K"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1112	by (intro emeasure_mono K)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1113	have "K' \<in> sets M"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1114	using me_K' by (rule measurable_envelopeD)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1115
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1116	have "min (outer_measure_of M {x\<in>K'. f x \<le> a}) (outer_measure_of M {x\<in>K'. b n \<le> f x}) < emeasure M K'"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1117	proof (rule assms)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1118	show "0 < emeasure M K'" "emeasure M K' < \<infinity>"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1119	using measurable_envelopeD2[OF me_K'] pos_b K K'_le_K by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1120	qed fact+
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1121	also have "{x\<in>K'. f x \<le> a} = K' \<inter> (K \<inter> ?E a)"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1122	using \<open>K' \<in> sets M\<close>[THEN sets.sets_into_space] \<open>K' \<subseteq> K\<close> by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1123	also have "{x\<in>K'. b n \<le> f x} = K' \<inter> (K \<inter> ?F (b n))"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1124	using \<open>K' \<in> sets M\<close>[THEN sets.sets_into_space] \<open>K' \<subseteq> K\<close> by auto
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1125	finally have "min (emeasure M K) (emeasure M K') < emeasure M K'"
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1126	unfolding
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1127	measurable_envelopeD(3)[OF me_K \<open>K' \<in> sets M\<close>, symmetric]
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1128	measurable_envelopeD(3)[OF me_K' \<open>K' \<in> sets M\<close>, symmetric]
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1129	using \<open>K' \<subseteq> K\<close> by (simp add: Int_absorb1 Int_absorb2)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1130	with K'_le_K show False
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1131	by (auto simp: min_def split: if_split_asm)
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1132	qed
0d82c4c94014 prove HK-integrable implies Lebesgue measurable; prove HK-integral equals Lebesgue integral for nonneg functions hoelzl parents: 63627 diff changeset	1133
40859 de0b30e6c2d2 Support product spaces on sigma finite measures. hoelzl parents: diff changeset	1134	end

author	hoelzl
	Tue, 18 Oct 2016 12:01:54 +0200
changeset 64284	f3b905b2eee2
parent 63968	4359400adfe7
child 67982	7643b005b29a
permissions	-rw-r--r--