(* Title: HOL/Probability/Measure.thy
Author: Lawrence C Paulson
Author: Johannes Hölzl, TU München
Author: Armin Heller, TU München
*)
header {* Properties about measure spaces *}
theory Measure
imports Caratheodory
begin
lemma measure_algebra_more[simp]:
"\<lparr> space = A, sets = B, \<dots> = algebra.more M \<rparr> \<lparr> measure := m \<rparr> =
\<lparr> space = A, sets = B, \<dots> = algebra.more (M \<lparr> measure := m \<rparr>) \<rparr>"
by (cases M) simp
lemma measure_algebra_more_eq[simp]:
"\<And>X. measure \<lparr> space = T, sets = A, \<dots> = algebra.more X \<rparr> = measure X"
unfolding measure_space.splits by simp
lemma measure_sigma[simp]: "measure (sigma A) = measure A"
unfolding sigma_def by simp
lemma algebra_measure_update[simp]:
"algebra (M'\<lparr>measure := m\<rparr>) \<longleftrightarrow> algebra M'"
unfolding algebra_iff_Un by simp
lemma sigma_algebra_measure_update[simp]:
"sigma_algebra (M'\<lparr>measure := m\<rparr>) \<longleftrightarrow> sigma_algebra M'"
unfolding sigma_algebra_def sigma_algebra_axioms_def by simp
lemma finite_sigma_algebra_measure_update[simp]:
"finite_sigma_algebra (M'\<lparr>measure := m\<rparr>) \<longleftrightarrow> finite_sigma_algebra M'"
unfolding finite_sigma_algebra_def finite_sigma_algebra_axioms_def by simp
lemma measurable_cancel_measure[simp]:
"measurable M1 (M2\<lparr>measure := m2\<rparr>) = measurable M1 M2"
"measurable (M2\<lparr>measure := m1\<rparr>) M1 = measurable M2 M1"
unfolding measurable_def by auto
lemma inj_on_image_eq_iff:
assumes "inj_on f S"
assumes "A \<subseteq> S" "B \<subseteq> S"
shows "(f ` A = f ` B) \<longleftrightarrow> (A = B)"
proof -
have "inj_on f (A \<union> B)"
using assms by (auto intro: subset_inj_on)
from inj_on_Un_image_eq_iff[OF this]
show ?thesis .
qed
lemma image_vimage_inter_eq:
assumes "f ` S = T" "X \<subseteq> T"
shows "f ` (f -` X \<inter> S) = X"
proof (intro antisym)
have "f ` (f -` X \<inter> S) \<subseteq> f ` (f -` X)" by auto
also have "\<dots> = X \<inter> range f" by simp
also have "\<dots> = X" using assms by auto
finally show "f ` (f -` X \<inter> S) \<subseteq> X" by auto
next
show "X \<subseteq> f ` (f -` X \<inter> S)"
proof
fix x assume "x \<in> X"
then have "x \<in> T" using `X \<subseteq> T` by auto
then obtain y where "x = f y" "y \<in> S"
using assms by auto
then have "{y} \<subseteq> f -` X \<inter> S" using `x \<in> X` by auto
moreover have "x \<in> f ` {y}" using `x = f y` by auto
ultimately show "x \<in> f ` (f -` X \<inter> S)" by auto
qed
qed
text {*
This formalisation of measure theory is based on the work of Hurd/Coble wand
was later translated by Lawrence Paulson to Isabelle/HOL. Later it was
modified to use the positive infinite reals and to prove the uniqueness of
cut stable measures.
*}
section {* Equations for the measure function @{text \<mu>} *}
lemma (in measure_space) measure_countably_additive:
assumes "range A \<subseteq> sets M" "disjoint_family A"
shows "(\<Sum>i. \<mu> (A i)) = \<mu> (\<Union>i. A i)"
proof -
have "(\<Union> i. A i) \<in> sets M" using assms(1) by (rule countable_UN)
with ca assms show ?thesis by (simp add: countably_additive_def)
qed
lemma (in sigma_algebra) sigma_algebra_cong:
assumes "space N = space M" "sets N = sets M"
shows "sigma_algebra N"
by default (insert sets_into_space, auto simp: assms)
lemma (in measure_space) measure_space_cong:
assumes "\<And>A. A \<in> sets M \<Longrightarrow> measure N A = \<mu> A" "space N = space M" "sets N = sets M"
shows "measure_space N"
proof -
interpret N: sigma_algebra N by (intro sigma_algebra_cong assms)
show ?thesis
proof
show "positive N (measure N)" using assms by (auto simp: positive_def)
show "countably_additive N (measure N)" unfolding countably_additive_def
proof safe
fix A :: "nat \<Rightarrow> 'a set" assume A: "range A \<subseteq> sets N" "disjoint_family A"
then have "\<And>i. A i \<in> sets M" "(UNION UNIV A) \<in> sets M" unfolding assms by auto
from measure_countably_additive[of A] A this[THEN assms(1)]
show "(\<Sum>n. measure N (A n)) = measure N (UNION UNIV A)"
unfolding assms by simp
qed
qed
qed
lemma (in measure_space) additive: "additive M \<mu>"
using ca by (auto intro!: countably_additive_additive simp: positive_def)
lemma (in measure_space) measure_additive:
"a \<in> sets M \<Longrightarrow> b \<in> sets M \<Longrightarrow> a \<inter> b = {}
\<Longrightarrow> \<mu> a + \<mu> b = \<mu> (a \<union> b)"
by (metis additiveD additive)
lemma (in measure_space) measure_mono:
assumes "a \<subseteq> b" "a \<in> sets M" "b \<in> sets M"
shows "\<mu> a \<le> \<mu> b"
proof -
have "b = a \<union> (b - a)" using assms by auto
moreover have "{} = a \<inter> (b - a)" by auto
ultimately have "\<mu> b = \<mu> a + \<mu> (b - a)"
using measure_additive[of a "b - a"] Diff[of b a] assms by auto
moreover have "\<mu> a + 0 \<le> \<mu> a + \<mu> (b - a)" using assms by (intro add_mono) auto
ultimately show "\<mu> a \<le> \<mu> b" by auto
qed
lemma (in measure_space) measure_compl:
assumes s: "s \<in> sets M" and fin: "\<mu> s \<noteq> \<infinity>"
shows "\<mu> (space M - s) = \<mu> (space M) - \<mu> s"
proof -
have s_less_space: "\<mu> s \<le> \<mu> (space M)"
using s by (auto intro!: measure_mono sets_into_space)
from s have "0 \<le> \<mu> s" by auto
have "\<mu> (space M) = \<mu> (s \<union> (space M - s))" using s
by (metis Un_Diff_cancel Un_absorb1 s sets_into_space)
also have "... = \<mu> s + \<mu> (space M - s)"
by (rule additiveD [OF additive]) (auto simp add: s)
finally have "\<mu> (space M) = \<mu> s + \<mu> (space M - s)" .
then show ?thesis
using fin `0 \<le> \<mu> s`
unfolding extreal_eq_minus_iff by (auto simp: ac_simps)
qed
lemma (in measure_space) measure_Diff:
assumes finite: "\<mu> B \<noteq> \<infinity>"
and measurable: "A \<in> sets M" "B \<in> sets M" "B \<subseteq> A"
shows "\<mu> (A - B) = \<mu> A - \<mu> B"
proof -
have "0 \<le> \<mu> B" using assms by auto
have "(A - B) \<union> B = A" using `B \<subseteq> A` by auto
then have "\<mu> A = \<mu> ((A - B) \<union> B)" by simp
also have "\<dots> = \<mu> (A - B) + \<mu> B"
using measurable by (subst measure_additive[symmetric]) auto
finally show "\<mu> (A - B) = \<mu> A - \<mu> B"
unfolding extreal_eq_minus_iff
using finite `0 \<le> \<mu> B` by auto
qed
lemma (in measure_space) measure_countable_increasing:
assumes A: "range A \<subseteq> sets M"
and A0: "A 0 = {}"
and ASuc: "\<And>n. A n \<subseteq> A (Suc n)"
shows "(SUP n. \<mu> (A n)) = \<mu> (\<Union>i. A i)"
proof -
{ fix n
have "\<mu> (A n) = (\<Sum>i<n. \<mu> (A (Suc i) - A i))"
proof (induct n)
case 0 thus ?case by (auto simp add: A0)
next
case (Suc m)
have "A (Suc m) = A m \<union> (A (Suc m) - A m)"
by (metis ASuc Un_Diff_cancel Un_absorb1)
hence "\<mu> (A (Suc m)) =
\<mu> (A m) + \<mu> (A (Suc m) - A m)"
by (subst measure_additive)
(auto simp add: measure_additive range_subsetD [OF A])
with Suc show ?case
by simp
qed }
note Meq = this
have Aeq: "(\<Union>i. A (Suc i) - A i) = (\<Union>i. A i)"
proof (rule UN_finite2_eq [where k=1], simp)
fix i
show "(\<Union>i\<in>{0..<i}. A (Suc i) - A i) = (\<Union>i\<in>{0..<Suc i}. A i)"
proof (induct i)
case 0 thus ?case by (simp add: A0)
next
case (Suc i)
thus ?case
by (auto simp add: atLeastLessThanSuc intro: subsetD [OF ASuc])
qed
qed
have A1: "\<And>i. A (Suc i) - A i \<in> sets M"
by (metis A Diff range_subsetD)
have A2: "(\<Union>i. A (Suc i) - A i) \<in> sets M"
by (blast intro: range_subsetD [OF A])
have "(SUP n. \<Sum>i<n. \<mu> (A (Suc i) - A i)) = (\<Sum>i. \<mu> (A (Suc i) - A i))"
using A by (auto intro!: suminf_extreal_eq_SUPR[symmetric])
also have "\<dots> = \<mu> (\<Union>i. A (Suc i) - A i)"
by (rule measure_countably_additive)
(auto simp add: disjoint_family_Suc ASuc A1 A2)
also have "... = \<mu> (\<Union>i. A i)"
by (simp add: Aeq)
finally have "(SUP n. \<Sum>i<n. \<mu> (A (Suc i) - A i)) = \<mu> (\<Union>i. A i)" .
then show ?thesis by (auto simp add: Meq)
qed
lemma (in measure_space) continuity_from_below:
assumes A: "range A \<subseteq> sets M" and "incseq A"
shows "(SUP n. \<mu> (A n)) = \<mu> (\<Union>i. A i)"
proof -
have *: "(SUP n. \<mu> (nat_case {} A (Suc n))) = (SUP n. \<mu> (nat_case {} A n))"
using A by (auto intro!: SUPR_eq exI split: nat.split)
have ueq: "(\<Union>i. nat_case {} A i) = (\<Union>i. A i)"
by (auto simp add: split: nat.splits)
have meq: "\<And>n. \<mu> (A n) = (\<mu> \<circ> nat_case {} A) (Suc n)"
by simp
have "(SUP n. \<mu> (nat_case {} A n)) = \<mu> (\<Union>i. nat_case {} A i)"
using range_subsetD[OF A] incseq_SucD[OF `incseq A`]
by (force split: nat.splits intro!: measure_countable_increasing)
also have "\<mu> (\<Union>i. nat_case {} A i) = \<mu> (\<Union>i. A i)"
by (simp add: ueq)
finally have "(SUP n. \<mu> (nat_case {} A n)) = \<mu> (\<Union>i. A i)" .
thus ?thesis unfolding meq * comp_def .
qed
lemma (in measure_space) measure_incseq:
assumes "range B \<subseteq> sets M" "incseq B"
shows "incseq (\<lambda>i. \<mu> (B i))"
using assms by (auto simp: incseq_def intro!: measure_mono)
lemma (in measure_space) continuity_from_below_Lim:
assumes A: "range A \<subseteq> sets M" "incseq A"
shows "(\<lambda>i. (\<mu> (A i))) ----> \<mu> (\<Union>i. A i)"
using LIMSEQ_extreal_SUPR[OF measure_incseq, OF A]
continuity_from_below[OF A] by simp
lemma (in measure_space) measure_decseq:
assumes "range B \<subseteq> sets M" "decseq B"
shows "decseq (\<lambda>i. \<mu> (B i))"
using assms by (auto simp: decseq_def intro!: measure_mono)
lemma (in measure_space) continuity_from_above:
assumes A: "range A \<subseteq> sets M" and "decseq A"
and finite: "\<And>i. \<mu> (A i) \<noteq> \<infinity>"
shows "(INF n. \<mu> (A n)) = \<mu> (\<Inter>i. A i)"
proof -
have le_MI: "\<mu> (\<Inter>i. A i) \<le> \<mu> (A 0)"
using A by (auto intro!: measure_mono)
hence *: "\<mu> (\<Inter>i. A i) \<noteq> \<infinity>" using finite[of 0] by auto
have A0: "0 \<le> \<mu> (A 0)" using A by auto
have "\<mu> (A 0) - (INF n. \<mu> (A n)) = \<mu> (A 0) + (SUP n. - \<mu> (A n))"
by (simp add: extreal_SUPR_uminus minus_extreal_def)
also have "\<dots> = (SUP n. \<mu> (A 0) - \<mu> (A n))"
unfolding minus_extreal_def using A0 assms
by (subst SUPR_extreal_add) (auto simp add: measure_decseq)
also have "\<dots> = (SUP n. \<mu> (A 0 - A n))"
using A finite `decseq A`[unfolded decseq_def] by (subst measure_Diff) auto
also have "\<dots> = \<mu> (\<Union>i. A 0 - A i)"
proof (rule continuity_from_below)
show "range (\<lambda>n. A 0 - A n) \<subseteq> sets M"
using A by auto
show "incseq (\<lambda>n. A 0 - A n)"
using `decseq A` by (auto simp add: incseq_def decseq_def)
qed
also have "\<dots> = \<mu> (A 0) - \<mu> (\<Inter>i. A i)"
using A finite * by (simp, subst measure_Diff) auto
finally show ?thesis
unfolding extreal_minus_eq_minus_iff using finite A0 by auto
qed
lemma (in measure_space) measure_insert:
assumes sets: "{x} \<in> sets M" "A \<in> sets M" and "x \<notin> A"
shows "\<mu> (insert x A) = \<mu> {x} + \<mu> A"
proof -
have "{x} \<inter> A = {}" using `x \<notin> A` by auto
from measure_additive[OF sets this] show ?thesis by simp
qed
lemma (in measure_space) measure_setsum:
assumes "finite S" and "\<And>i. i \<in> S \<Longrightarrow> A i \<in> sets M"
assumes disj: "disjoint_family_on A S"
shows "(\<Sum>i\<in>S. \<mu> (A i)) = \<mu> (\<Union>i\<in>S. A i)"
using assms proof induct
case (insert i S)
then have "(\<Sum>i\<in>S. \<mu> (A i)) = \<mu> (\<Union>a\<in>S. A a)"
by (auto intro: disjoint_family_on_mono)
moreover have "A i \<inter> (\<Union>a\<in>S. A a) = {}"
using `disjoint_family_on A (insert i S)` `i \<notin> S`
by (auto simp: disjoint_family_on_def)
ultimately show ?case using insert
by (auto simp: measure_additive finite_UN)
qed simp
lemma (in measure_space) measure_finite_singleton:
assumes "finite S" "\<And>x. x \<in> S \<Longrightarrow> {x} \<in> sets M"
shows "\<mu> S = (\<Sum>x\<in>S. \<mu> {x})"
using measure_setsum[of S "\<lambda>x. {x}", OF assms]
by (auto simp: disjoint_family_on_def)
lemma finite_additivity_sufficient:
assumes "sigma_algebra M"
assumes fin: "finite (space M)" and pos: "positive M (measure M)" and add: "additive M (measure M)"
shows "measure_space M"
proof -
interpret sigma_algebra M by fact
show ?thesis
proof
show [simp]: "positive M (measure M)" using pos by (simp add: positive_def)
show "countably_additive M (measure M)"
proof (auto simp add: countably_additive_def)
fix A :: "nat \<Rightarrow> 'a set"
assume A: "range A \<subseteq> sets M"
and disj: "disjoint_family A"
and UnA: "(\<Union>i. A i) \<in> sets M"
def I \<equiv> "{i. A i \<noteq> {}}"
have "Union (A ` I) \<subseteq> space M" using A
by auto (metis range_subsetD subsetD sets_into_space)
hence "finite (A ` I)"
by (metis finite_UnionD finite_subset fin)
moreover have "inj_on A I" using disj
by (auto simp add: I_def disjoint_family_on_def inj_on_def)
ultimately have finI: "finite I"
by (metis finite_imageD)
hence "\<exists>N. \<forall>m\<ge>N. A m = {}"
proof (cases "I = {}")
case True thus ?thesis by (simp add: I_def)
next
case False
hence "\<forall>i\<in>I. i < Suc(Max I)"
by (simp add: Max_less_iff [symmetric] finI)
hence "\<forall>m \<ge> Suc(Max I). A m = {}"
by (simp add: I_def) (metis less_le_not_le)
thus ?thesis
by blast
qed
then obtain N where N: "\<forall>m\<ge>N. A m = {}" by blast
then have "\<forall>m\<ge>N. measure M (A m) = 0" using pos[unfolded positive_def] by simp
then have "(\<Sum>n. measure M (A n)) = (\<Sum>m<N. measure M (A m))"
by (simp add: suminf_finite)
also have "... = measure M (\<Union>i<N. A i)"
proof (induct N)
case 0 thus ?case using pos[unfolded positive_def] by simp
next
case (Suc n)
have "measure M (A n \<union> (\<Union> x<n. A x)) = measure M (A n) + measure M (\<Union> i<n. A i)"
proof (rule Caratheodory.additiveD [OF add])
show "A n \<inter> (\<Union> x<n. A x) = {}" using disj
by (auto simp add: disjoint_family_on_def nat_less_le) blast
show "A n \<in> sets M" using A
by force
show "(\<Union>i<n. A i) \<in> sets M"
proof (induct n)
case 0 thus ?case by simp
next
case (Suc n) thus ?case using A
by (simp add: lessThan_Suc Un range_subsetD)
qed
qed
thus ?case using Suc
by (simp add: lessThan_Suc)
qed
also have "... = measure M (\<Union>i. A i)"
proof -
have "(\<Union> i<N. A i) = (\<Union>i. A i)" using N
by auto (metis Int_absorb N disjoint_iff_not_equal lessThan_iff not_leE)
thus ?thesis by simp
qed
finally show "(\<Sum>n. measure M (A n)) = measure M (\<Union>i. A i)" .
qed
qed
qed
lemma (in measure_space) measure_setsum_split:
assumes "finite S" and "A \<in> sets M" and br_in_M: "B ` S \<subseteq> sets M"
assumes "(\<Union>i\<in>S. B i) = space M"
assumes "disjoint_family_on B S"
shows "\<mu> A = (\<Sum>i\<in>S. \<mu> (A \<inter> (B i)))"
proof -
have *: "\<mu> A = \<mu> (\<Union>i\<in>S. A \<inter> B i)"
using assms by auto
show ?thesis unfolding *
proof (rule measure_setsum[symmetric])
show "disjoint_family_on (\<lambda>i. A \<inter> B i) S"
using `disjoint_family_on B S`
unfolding disjoint_family_on_def by auto
qed (insert assms, auto)
qed
lemma (in measure_space) measure_subadditive:
assumes measurable: "A \<in> sets M" "B \<in> sets M"
shows "\<mu> (A \<union> B) \<le> \<mu> A + \<mu> B"
proof -
from measure_additive[of A "B - A"]
have "\<mu> (A \<union> B) = \<mu> A + \<mu> (B - A)"
using assms by (simp add: Diff)
also have "\<dots> \<le> \<mu> A + \<mu> B"
using assms by (auto intro!: add_left_mono measure_mono)
finally show ?thesis .
qed
lemma (in measure_space) measure_eq_0:
assumes "N \<in> sets M" and "\<mu> N = 0" and "K \<subseteq> N" and "K \<in> sets M"
shows "\<mu> K = 0"
using measure_mono[OF assms(3,4,1)] assms(2) positive_measure[OF assms(4)] by auto
lemma (in measure_space) measure_finitely_subadditive:
assumes "finite I" "A ` I \<subseteq> sets M"
shows "\<mu> (\<Union>i\<in>I. A i) \<le> (\<Sum>i\<in>I. \<mu> (A i))"
using assms proof induct
case (insert i I)
then have "(\<Union>i\<in>I. A i) \<in> sets M" by (auto intro: finite_UN)
then have "\<mu> (\<Union>i\<in>insert i I. A i) \<le> \<mu> (A i) + \<mu> (\<Union>i\<in>I. A i)"
using insert by (simp add: measure_subadditive)
also have "\<dots> \<le> (\<Sum>i\<in>insert i I. \<mu> (A i))"
using insert by (auto intro!: add_left_mono)
finally show ?case .
qed simp
lemma (in measure_space) measure_countably_subadditive:
assumes "range f \<subseteq> sets M"
shows "\<mu> (\<Union>i. f i) \<le> (\<Sum>i. \<mu> (f i))"
proof -
have "\<mu> (\<Union>i. f i) = \<mu> (\<Union>i. disjointed f i)"
unfolding UN_disjointed_eq ..
also have "\<dots> = (\<Sum>i. \<mu> (disjointed f i))"
using range_disjointed_sets[OF assms] measure_countably_additive
by (simp add: disjoint_family_disjointed comp_def)
also have "\<dots> \<le> (\<Sum>i. \<mu> (f i))"
using range_disjointed_sets[OF assms] assms
by (auto intro!: suminf_le_pos measure_mono positive_measure disjointed_subset)
finally show ?thesis .
qed
lemma (in measure_space) measure_UN_eq_0:
assumes "\<And>i::nat. \<mu> (N i) = 0" and "range N \<subseteq> sets M"
shows "\<mu> (\<Union> i. N i) = 0"
proof -
have "0 \<le> \<mu> (\<Union> i. N i)" using assms by auto
moreover have "\<mu> (\<Union> i. N i) \<le> 0"
using measure_countably_subadditive[OF assms(2)] assms(1) by simp
ultimately show ?thesis by simp
qed
lemma (in measure_space) measure_inter_full_set:
assumes "S \<in> sets M" "T \<in> sets M" and fin: "\<mu> (T - S) \<noteq> \<infinity>"
assumes T: "\<mu> T = \<mu> (space M)"
shows "\<mu> (S \<inter> T) = \<mu> S"
proof (rule antisym)
show " \<mu> (S \<inter> T) \<le> \<mu> S"
using assms by (auto intro!: measure_mono)
have pos: "0 \<le> \<mu> (T - S)" using assms by auto
show "\<mu> S \<le> \<mu> (S \<inter> T)"
proof (rule ccontr)
assume contr: "\<not> ?thesis"
have "\<mu> (space M) = \<mu> ((T - S) \<union> (S \<inter> T))"
unfolding T[symmetric] by (auto intro!: arg_cong[where f="\<mu>"])
also have "\<dots> \<le> \<mu> (T - S) + \<mu> (S \<inter> T)"
using assms by (auto intro!: measure_subadditive)
also have "\<dots> < \<mu> (T - S) + \<mu> S"
using fin contr pos by (intro extreal_less_add) auto
also have "\<dots> = \<mu> (T \<union> S)"
using assms by (subst measure_additive) auto
also have "\<dots> \<le> \<mu> (space M)"
using assms sets_into_space by (auto intro!: measure_mono)
finally show False ..
qed
qed
lemma measure_unique_Int_stable:
fixes E :: "('a, 'b) algebra_scheme" and A :: "nat \<Rightarrow> 'a set"
assumes "Int_stable E"
and A: "range A \<subseteq> sets E" "incseq A" "(\<Union>i. A i) = space E"
and M: "measure_space \<lparr>space = space E, sets = sets (sigma E), measure = \<mu>\<rparr>" (is "measure_space ?M")
and N: "measure_space \<lparr>space = space E, sets = sets (sigma E), measure = \<nu>\<rparr>" (is "measure_space ?N")
and eq: "\<And>X. X \<in> sets E \<Longrightarrow> \<mu> X = \<nu> X"
and finite: "\<And>i. \<mu> (A i) \<noteq> \<infinity>"
assumes "X \<in> sets (sigma E)"
shows "\<mu> X = \<nu> X"
proof -
let "?D F" = "{D. D \<in> sets (sigma E) \<and> \<mu> (F \<inter> D) = \<nu> (F \<inter> D)}"
interpret M: measure_space ?M
where "space ?M = space E" and "sets ?M = sets (sigma E)" and "measure ?M = \<mu>" by (simp_all add: M)
interpret N: measure_space ?N
where "space ?N = space E" and "sets ?N = sets (sigma E)" and "measure ?N = \<nu>" by (simp_all add: N)
{ fix F assume "F \<in> sets E" and "\<mu> F \<noteq> \<infinity>"
then have [intro]: "F \<in> sets (sigma E)" by auto
have "\<nu> F \<noteq> \<infinity>" using `\<mu> F \<noteq> \<infinity>` `F \<in> sets E` eq by simp
interpret D: dynkin_system "\<lparr>space=space E, sets=?D F\<rparr>"
proof (rule dynkin_systemI, simp_all)
fix A assume "A \<in> sets (sigma E) \<and> \<mu> (F \<inter> A) = \<nu> (F \<inter> A)"
then show "A \<subseteq> space E" using M.sets_into_space by auto
next
have "F \<inter> space E = F" using `F \<in> sets E` by auto
then show "\<mu> (F \<inter> space E) = \<nu> (F \<inter> space E)"
using `F \<in> sets E` eq by auto
next
fix A assume *: "A \<in> sets (sigma E) \<and> \<mu> (F \<inter> A) = \<nu> (F \<inter> A)"
then have **: "F \<inter> (space (sigma E) - A) = F - (F \<inter> A)"
and [intro]: "F \<inter> A \<in> sets (sigma E)"
using `F \<in> sets E` M.sets_into_space by auto
have "\<nu> (F \<inter> A) \<le> \<nu> F" by (auto intro!: N.measure_mono)
then have "\<nu> (F \<inter> A) \<noteq> \<infinity>" using `\<nu> F \<noteq> \<infinity>` by auto
have "\<mu> (F \<inter> A) \<le> \<mu> F" by (auto intro!: M.measure_mono)
then have "\<mu> (F \<inter> A) \<noteq> \<infinity>" using `\<mu> F \<noteq> \<infinity>` by auto
then have "\<mu> (F \<inter> (space (sigma E) - A)) = \<mu> F - \<mu> (F \<inter> A)" unfolding **
using `F \<inter> A \<in> sets (sigma E)` by (auto intro!: M.measure_Diff)
also have "\<dots> = \<nu> F - \<nu> (F \<inter> A)" using eq `F \<in> sets E` * by simp
also have "\<dots> = \<nu> (F \<inter> (space (sigma E) - A))" unfolding **
using `F \<inter> A \<in> sets (sigma E)` `\<nu> (F \<inter> A) \<noteq> \<infinity>` by (auto intro!: N.measure_Diff[symmetric])
finally show "space E - A \<in> sets (sigma E) \<and> \<mu> (F \<inter> (space E - A)) = \<nu> (F \<inter> (space E - A))"
using * by auto
next
fix A :: "nat \<Rightarrow> 'a set"
assume "disjoint_family A" "range A \<subseteq> {X \<in> sets (sigma E). \<mu> (F \<inter> X) = \<nu> (F \<inter> X)}"
then have A: "range (\<lambda>i. F \<inter> A i) \<subseteq> sets (sigma E)" "F \<inter> (\<Union>x. A x) = (\<Union>x. F \<inter> A x)"
"disjoint_family (\<lambda>i. F \<inter> A i)" "\<And>i. \<mu> (F \<inter> A i) = \<nu> (F \<inter> A i)" "range A \<subseteq> sets (sigma E)"
by (auto simp: disjoint_family_on_def subset_eq)
then show "(\<Union>x. A x) \<in> sets (sigma E) \<and> \<mu> (F \<inter> (\<Union>x. A x)) = \<nu> (F \<inter> (\<Union>x. A x))"
by (auto simp: M.measure_countably_additive[symmetric]
N.measure_countably_additive[symmetric]
simp del: UN_simps)
qed
have *: "sets (sigma E) = sets \<lparr>space = space E, sets = ?D F\<rparr>"
using `F \<in> sets E` `Int_stable E`
by (intro D.dynkin_lemma)
(auto simp add: sets_sigma Int_stable_def eq intro: sigma_sets.Basic)
have "\<And>D. D \<in> sets (sigma E) \<Longrightarrow> \<mu> (F \<inter> D) = \<nu> (F \<inter> D)"
by (subst (asm) *) auto }
note * = this
let "?A i" = "A i \<inter> X"
have A': "range ?A \<subseteq> sets (sigma E)" "incseq ?A"
using A(1,2) `X \<in> sets (sigma E)` by (auto simp: incseq_def)
{ fix i have "\<mu> (?A i) = \<nu> (?A i)"
using *[of "A i" X] `X \<in> sets (sigma E)` A finite by auto }
with M.continuity_from_below[OF A'] N.continuity_from_below[OF A']
show ?thesis using A(3) `X \<in> sets (sigma E)` by auto
qed
section "@{text \<mu>}-null sets"
abbreviation (in measure_space) "null_sets \<equiv> {N\<in>sets M. \<mu> N = 0}"
sublocale measure_space \<subseteq> nullsets!: ring_of_sets "\<lparr> space = space M, sets = null_sets \<rparr>"
where "space \<lparr> space = space M, sets = null_sets \<rparr> = space M"
and "sets \<lparr> space = space M, sets = null_sets \<rparr> = null_sets"
proof -
{ fix A B assume sets: "A \<in> sets M" "B \<in> sets M"
moreover then have "\<mu> (A \<union> B) \<le> \<mu> A + \<mu> B" "\<mu> (A - B) \<le> \<mu> A"
by (auto intro!: measure_subadditive measure_mono)
moreover assume "\<mu> B = 0" "\<mu> A = 0"
ultimately have "\<mu> (A - B) = 0" "\<mu> (A \<union> B) = 0"
by (auto intro!: antisym) }
note null = this
show "ring_of_sets \<lparr> space = space M, sets = null_sets \<rparr>"
by default (insert sets_into_space null, auto)
qed simp_all
lemma UN_from_nat: "(\<Union>i. N i) = (\<Union>i. N (Countable.from_nat i))"
proof -
have "(\<Union>i. N i) = (\<Union>i. (N \<circ> Countable.from_nat) i)"
unfolding SUPR_def image_compose
unfolding surj_from_nat ..
then show ?thesis by simp
qed
lemma (in measure_space) null_sets_UN[intro]:
assumes "\<And>i::'i::countable. N i \<in> null_sets"
shows "(\<Union>i. N i) \<in> null_sets"
proof (intro conjI CollectI)
show "(\<Union>i. N i) \<in> sets M" using assms by auto
then have "0 \<le> \<mu> (\<Union>i. N i)" by simp
moreover have "\<mu> (\<Union>i. N i) \<le> (\<Sum>n. \<mu> (N (Countable.from_nat n)))"
unfolding UN_from_nat[of N]
using assms by (intro measure_countably_subadditive) auto
ultimately show "\<mu> (\<Union>i. N i) = 0" using assms by auto
qed
lemma (in measure_space) null_set_Int1:
assumes "B \<in> null_sets" "A \<in> sets M" shows "A \<inter> B \<in> null_sets"
using assms proof (intro CollectI conjI)
show "\<mu> (A \<inter> B) = 0" using assms by (intro measure_eq_0[of B "A \<inter> B"]) auto
qed auto
lemma (in measure_space) null_set_Int2:
assumes "B \<in> null_sets" "A \<in> sets M" shows "B \<inter> A \<in> null_sets"
using assms by (subst Int_commute) (rule null_set_Int1)
lemma (in measure_space) measure_Diff_null_set:
assumes "B \<in> null_sets" "A \<in> sets M"
shows "\<mu> (A - B) = \<mu> A"
proof -
have *: "A - B = (A - (A \<inter> B))" by auto
have "A \<inter> B \<in> null_sets" using assms by (rule null_set_Int1)
then show ?thesis
unfolding * using assms
by (subst measure_Diff) auto
qed
lemma (in measure_space) null_set_Diff:
assumes "B \<in> null_sets" "A \<in> sets M" shows "B - A \<in> null_sets"
using assms proof (intro CollectI conjI)
show "\<mu> (B - A) = 0" using assms by (intro measure_eq_0[of B "B - A"]) auto
qed auto
lemma (in measure_space) measure_Un_null_set:
assumes "A \<in> sets M" "B \<in> null_sets"
shows "\<mu> (A \<union> B) = \<mu> A"
proof -
have *: "A \<union> B = A \<union> (B - A)" by auto
have "B - A \<in> null_sets" using assms(2,1) by (rule null_set_Diff)
then show ?thesis
unfolding * using assms
by (subst measure_additive[symmetric]) auto
qed
section "Formalise almost everywhere"
definition (in measure_space)
almost_everywhere :: "('a \<Rightarrow> bool) \<Rightarrow> bool" (binder "AE " 10) where
"almost_everywhere P \<longleftrightarrow> (\<exists>N\<in>null_sets. { x \<in> space M. \<not> P x } \<subseteq> N)"
syntax
"_almost_everywhere" :: "'a \<Rightarrow> ('a, 'b) measure_space_scheme \<Rightarrow> ('a \<Rightarrow> bool) \<Rightarrow> bool" ("AE _ in _. _" [0,0,10] 10)
translations
"AE x in M. P" == "CONST measure_space.almost_everywhere M (%x. P)"
lemma (in measure_space) AE_cong_measure:
assumes "\<And>A. A \<in> sets M \<Longrightarrow> measure N A = \<mu> A" "sets N = sets M" "space N = space M"
shows "(AE x in N. P x) \<longleftrightarrow> (AE x. P x)"
proof -
interpret N: measure_space N
by (rule measure_space_cong) fact+
show ?thesis
unfolding N.almost_everywhere_def almost_everywhere_def
by (auto simp: assms)
qed
lemma (in measure_space) AE_I':
"N \<in> null_sets \<Longrightarrow> {x\<in>space M. \<not> P x} \<subseteq> N \<Longrightarrow> (AE x. P x)"
unfolding almost_everywhere_def by auto
lemma (in measure_space) AE_iff_null_set:
assumes "{x\<in>space M. \<not> P x} \<in> sets M" (is "?P \<in> sets M")
shows "(AE x. P x) \<longleftrightarrow> {x\<in>space M. \<not> P x} \<in> null_sets"
proof
assume "AE x. P x" then obtain N where N: "N \<in> sets M" "?P \<subseteq> N" "\<mu> N = 0"
unfolding almost_everywhere_def by auto
have "0 \<le> \<mu> ?P" using assms by simp
moreover have "\<mu> ?P \<le> \<mu> N"
using assms N(1,2) by (auto intro: measure_mono)
ultimately have "\<mu> ?P = 0" unfolding `\<mu> N = 0` by auto
then show "?P \<in> null_sets" using assms by simp
next
assume "?P \<in> null_sets" with assms show "AE x. P x" by (auto intro: AE_I')
qed
lemma (in measure_space) AE_iff_measurable:
"N \<in> sets M \<Longrightarrow> {x\<in>space M. \<not> P x} = N \<Longrightarrow> (AE x. P x) \<longleftrightarrow> \<mu> N = 0"
using AE_iff_null_set[of P] by simp
lemma (in measure_space) AE_True[intro, simp]: "AE x. True"
unfolding almost_everywhere_def by auto
lemma (in measure_space) AE_E[consumes 1]:
assumes "AE x. P x"
obtains N where "{x \<in> space M. \<not> P x} \<subseteq> N" "\<mu> N = 0" "N \<in> sets M"
using assms unfolding almost_everywhere_def by auto
lemma (in measure_space) AE_E2:
assumes "AE x. P x" "{x\<in>space M. P x} \<in> sets M"
shows "\<mu> {x\<in>space M. \<not> P x} = 0" (is "\<mu> ?P = 0")
proof -
have "{x\<in>space M. \<not> P x} = space M - {x\<in>space M. P x}"
by auto
with AE_iff_null_set[of P] assms show ?thesis by auto
qed
lemma (in measure_space) AE_I:
assumes "{x \<in> space M. \<not> P x} \<subseteq> N" "\<mu> N = 0" "N \<in> sets M"
shows "AE x. P x"
using assms unfolding almost_everywhere_def by auto
lemma (in measure_space) AE_mp[elim!]:
assumes AE_P: "AE x. P x" and AE_imp: "AE x. P x \<longrightarrow> Q x"
shows "AE x. Q x"
proof -
from AE_P obtain A where P: "{x\<in>space M. \<not> P x} \<subseteq> A"
and A: "A \<in> sets M" "\<mu> A = 0"
by (auto elim!: AE_E)
from AE_imp obtain B where imp: "{x\<in>space M. P x \<and> \<not> Q x} \<subseteq> B"
and B: "B \<in> sets M" "\<mu> B = 0"
by (auto elim!: AE_E)
show ?thesis
proof (intro AE_I)
have "0 \<le> \<mu> (A \<union> B)" using A B by auto
moreover have "\<mu> (A \<union> B) \<le> 0"
using measure_subadditive[of A B] A B by auto
ultimately show "A \<union> B \<in> sets M" "\<mu> (A \<union> B) = 0" using A B by auto
show "{x\<in>space M. \<not> Q x} \<subseteq> A \<union> B"
using P imp by auto
qed
qed
lemma (in measure_space)
shows AE_iffI: "AE x. P x \<Longrightarrow> AE x. P x \<longleftrightarrow> Q x \<Longrightarrow> AE x. Q x"
and AE_disjI1: "AE x. P x \<Longrightarrow> AE x. P x \<or> Q x"
and AE_disjI2: "AE x. Q x \<Longrightarrow> AE x. P x \<or> Q x"
and AE_conjI: "AE x. P x \<Longrightarrow> AE x. Q x \<Longrightarrow> AE x. P x \<and> Q x"
and AE_conj_iff[simp]: "(AE x. P x \<and> Q x) \<longleftrightarrow> (AE x. P x) \<and> (AE x. Q x)"
by auto
lemma (in measure_space) AE_space: "AE x. x \<in> space M"
by (rule AE_I[where N="{}"]) auto
lemma (in measure_space) AE_I2[simp, intro]:
"(\<And>x. x \<in> space M \<Longrightarrow> P x) \<Longrightarrow> AE x. P x"
using AE_space by auto
lemma (in measure_space) AE_Ball_mp:
"\<forall>x\<in>space M. P x \<Longrightarrow> AE x. P x \<longrightarrow> Q x \<Longrightarrow> AE x. Q x"
by auto
lemma (in measure_space) AE_cong[cong]:
"(\<And>x. x \<in> space M \<Longrightarrow> P x \<longleftrightarrow> Q x) \<Longrightarrow> (AE x. P x) \<longleftrightarrow> (AE x. Q x)"
by auto
lemma (in measure_space) AE_all_countable:
"(AE x. \<forall>i. P i x) \<longleftrightarrow> (\<forall>i::'i::countable. AE x. P i x)"
proof
assume "\<forall>i. AE x. P i x"
from this[unfolded almost_everywhere_def Bex_def, THEN choice]
obtain N where N: "\<And>i. N i \<in> null_sets" "\<And>i. {x\<in>space M. \<not> P i x} \<subseteq> N i" by auto
have "{x\<in>space M. \<not> (\<forall>i. P i x)} \<subseteq> (\<Union>i. {x\<in>space M. \<not> P i x})" by auto
also have "\<dots> \<subseteq> (\<Union>i. N i)" using N by auto
finally have "{x\<in>space M. \<not> (\<forall>i. P i x)} \<subseteq> (\<Union>i. N i)" .
moreover from N have "(\<Union>i. N i) \<in> null_sets"
by (intro null_sets_UN) auto
ultimately show "AE x. \<forall>i. P i x"
unfolding almost_everywhere_def by auto
qed auto
lemma (in measure_space) AE_finite_all:
assumes f: "finite S" shows "(AE x. \<forall>i\<in>S. P i x) \<longleftrightarrow> (\<forall>i\<in>S. AE x. P i x)"
using f by induct auto
lemma (in measure_space) restricted_measure_space:
assumes "S \<in> sets M"
shows "measure_space (restricted_space S)"
(is "measure_space ?r")
unfolding measure_space_def measure_space_axioms_def
proof safe
show "sigma_algebra ?r" using restricted_sigma_algebra[OF assms] .
show "positive ?r (measure ?r)" using `S \<in> sets M` by (auto simp: positive_def)
show "countably_additive ?r (measure ?r)"
unfolding countably_additive_def
proof safe
fix A :: "nat \<Rightarrow> 'a set"
assume *: "range A \<subseteq> sets ?r" and **: "disjoint_family A"
from restriction_in_sets[OF assms *[simplified]] **
show "(\<Sum>n. measure ?r (A n)) = measure ?r (\<Union>i. A i)"
using measure_countably_additive by simp
qed
qed
lemma (in measure_space) AE_restricted:
assumes "A \<in> sets M"
shows "(AE x in restricted_space A. P x) \<longleftrightarrow> (AE x. x \<in> A \<longrightarrow> P x)"
proof -
interpret R: measure_space "restricted_space A"
by (rule restricted_measure_space[OF `A \<in> sets M`])
show ?thesis
proof
assume "AE x in restricted_space A. P x"
from this[THEN R.AE_E] guess N' .
then obtain N where "{x \<in> A. \<not> P x} \<subseteq> A \<inter> N" "\<mu> (A \<inter> N) = 0" "N \<in> sets M"
by auto
moreover then have "{x \<in> space M. \<not> (x \<in> A \<longrightarrow> P x)} \<subseteq> A \<inter> N"
using `A \<in> sets M` sets_into_space by auto
ultimately show "AE x. x \<in> A \<longrightarrow> P x"
using `A \<in> sets M` by (auto intro!: AE_I[where N="A \<inter> N"])
next
assume "AE x. x \<in> A \<longrightarrow> P x"
from this[THEN AE_E] guess N .
then show "AE x in restricted_space A. P x"
using null_set_Int1[OF _ `A \<in> sets M`] `A \<in> sets M`[THEN sets_into_space]
by (auto intro!: R.AE_I[where N="A \<inter> N"] simp: subset_eq)
qed
qed
lemma (in measure_space) measure_space_subalgebra:
assumes "sigma_algebra N" and "sets N \<subseteq> sets M" "space N = space M"
and measure[simp]: "\<And>X. X \<in> sets N \<Longrightarrow> measure N X = measure M X"
shows "measure_space N"
proof -
interpret N: sigma_algebra N by fact
show ?thesis
proof
from `sets N \<subseteq> sets M` have "\<And>A. range A \<subseteq> sets N \<Longrightarrow> range A \<subseteq> sets M" by blast
then show "countably_additive N (measure N)"
by (auto intro!: measure_countably_additive simp: countably_additive_def subset_eq)
show "positive N (measure_space.measure N)"
using assms(2) by (auto simp add: positive_def)
qed
qed
lemma (in measure_space) AE_subalgebra:
assumes ae: "AE x in N. P x"
and N: "sets N \<subseteq> sets M" "space N = space M" "\<And>A. A \<in> sets N \<Longrightarrow> measure N A = \<mu> A"
and sa: "sigma_algebra N"
shows "AE x. P x"
proof -
interpret N: measure_space N using measure_space_subalgebra[OF sa N] .
from ae[THEN N.AE_E] guess N .
with N show ?thesis unfolding almost_everywhere_def by auto
qed
section "@{text \<sigma>}-finite Measures"
locale sigma_finite_measure = measure_space +
assumes sigma_finite: "\<exists>A::nat \<Rightarrow> 'a set. range A \<subseteq> sets M \<and> (\<Union>i. A i) = space M \<and> (\<forall>i. \<mu> (A i) \<noteq> \<infinity>)"
lemma (in sigma_finite_measure) restricted_sigma_finite_measure:
assumes "S \<in> sets M"
shows "sigma_finite_measure (restricted_space S)"
(is "sigma_finite_measure ?r")
unfolding sigma_finite_measure_def sigma_finite_measure_axioms_def
proof safe
show "measure_space ?r" using restricted_measure_space[OF assms] .
next
obtain A :: "nat \<Rightarrow> 'a set" where
"range A \<subseteq> sets M" "(\<Union>i. A i) = space M" "\<And>i. \<mu> (A i) \<noteq> \<infinity>"
using sigma_finite by auto
show "\<exists>A::nat \<Rightarrow> 'a set. range A \<subseteq> sets ?r \<and> (\<Union>i. A i) = space ?r \<and> (\<forall>i. measure ?r (A i) \<noteq> \<infinity>)"
proof (safe intro!: exI[of _ "\<lambda>i. A i \<inter> S"] del: notI)
fix i
show "A i \<inter> S \<in> sets ?r"
using `range A \<subseteq> sets M` `S \<in> sets M` by auto
next
fix x i assume "x \<in> S" thus "x \<in> space ?r" by simp
next
fix x assume "x \<in> space ?r" thus "x \<in> (\<Union>i. A i \<inter> S)"
using `(\<Union>i. A i) = space M` `S \<in> sets M` by auto
next
fix i
have "\<mu> (A i \<inter> S) \<le> \<mu> (A i)"
using `range A \<subseteq> sets M` `S \<in> sets M` by (auto intro!: measure_mono)
then show "measure ?r (A i \<inter> S) \<noteq> \<infinity>" using `\<mu> (A i) \<noteq> \<infinity>` by auto
qed
qed
lemma (in sigma_finite_measure) sigma_finite_measure_cong:
assumes cong: "\<And>A. A \<in> sets M \<Longrightarrow> measure M' A = \<mu> A" "sets M' = sets M" "space M' = space M"
shows "sigma_finite_measure M'"
proof -
interpret M': measure_space M' by (intro measure_space_cong cong)
from sigma_finite guess A .. note A = this
then have "\<And>i. A i \<in> sets M" by auto
with A have fin: "\<forall>i. measure M' (A i) \<noteq> \<infinity>" using cong by auto
show ?thesis
apply default
using A fin cong by auto
qed
lemma (in sigma_finite_measure) disjoint_sigma_finite:
"\<exists>A::nat\<Rightarrow>'a set. range A \<subseteq> sets M \<and> (\<Union>i. A i) = space M \<and>
(\<forall>i. \<mu> (A i) \<noteq> \<infinity>) \<and> disjoint_family A"
proof -
obtain A :: "nat \<Rightarrow> 'a set" where
range: "range A \<subseteq> sets M" and
space: "(\<Union>i. A i) = space M" and
measure: "\<And>i. \<mu> (A i) \<noteq> \<infinity>"
using sigma_finite by auto
note range' = range_disjointed_sets[OF range] range
{ fix i
have "\<mu> (disjointed A i) \<le> \<mu> (A i)"
using range' disjointed_subset[of A i] by (auto intro!: measure_mono)
then have "\<mu> (disjointed A i) \<noteq> \<infinity>"
using measure[of i] by auto }
with disjoint_family_disjointed UN_disjointed_eq[of A] space range'
show ?thesis by (auto intro!: exI[of _ "disjointed A"])
qed
lemma (in sigma_finite_measure) sigma_finite_up:
"\<exists>F. range F \<subseteq> sets M \<and> incseq F \<and> (\<Union>i. F i) = space M \<and> (\<forall>i. \<mu> (F i) \<noteq> \<infinity>)"
proof -
obtain F :: "nat \<Rightarrow> 'a set" where
F: "range F \<subseteq> sets M" "(\<Union>i. F i) = space M" "\<And>i. \<mu> (F i) \<noteq> \<infinity>"
using sigma_finite by auto
then show ?thesis
proof (intro exI[of _ "\<lambda>n. \<Union>i\<le>n. F i"] conjI allI)
from F have "\<And>x. x \<in> space M \<Longrightarrow> \<exists>i. x \<in> F i" by auto
then show "(\<Union>n. \<Union> i\<le>n. F i) = space M"
using F by fastsimp
next
fix n
have "\<mu> (\<Union> i\<le>n. F i) \<le> (\<Sum>i\<le>n. \<mu> (F i))" using F
by (auto intro!: measure_finitely_subadditive)
also have "\<dots> < \<infinity>"
using F by (auto simp: setsum_Pinfty)
finally show "\<mu> (\<Union> i\<le>n. F i) \<noteq> \<infinity>" by simp
qed (force simp: incseq_def)+
qed
section {* Measure preserving *}
definition "measure_preserving A B =
{f \<in> measurable A B. (\<forall>y \<in> sets B. measure B y = measure A (f -` y \<inter> space A))}"
lemma measure_preservingI[intro?]:
assumes "f \<in> measurable A B"
and "\<And>y. y \<in> sets B \<Longrightarrow> measure A (f -` y \<inter> space A) = measure B y"
shows "f \<in> measure_preserving A B"
unfolding measure_preserving_def using assms by auto
lemma (in measure_space) measure_space_vimage:
fixes M' :: "('c, 'd) measure_space_scheme"
assumes T: "sigma_algebra M'" "T \<in> measure_preserving M M'"
shows "measure_space M'"
proof -
interpret M': sigma_algebra M' by fact
show ?thesis
proof
show "positive M' (measure M')" using T
by (auto simp: measure_preserving_def positive_def measurable_sets)
show "countably_additive M' (measure M')"
proof (intro countably_additiveI)
fix A :: "nat \<Rightarrow> 'c set" assume "range A \<subseteq> sets M'" "disjoint_family A"
then have A: "\<And>i. A i \<in> sets M'" "(\<Union>i. A i) \<in> sets M'" by auto
then have *: "range (\<lambda>i. T -` (A i) \<inter> space M) \<subseteq> sets M"
using T by (auto simp: measurable_def measure_preserving_def)
moreover have "(\<Union>i. T -` A i \<inter> space M) \<in> sets M"
using * by blast
moreover have **: "disjoint_family (\<lambda>i. T -` A i \<inter> space M)"
using `disjoint_family A` by (auto simp: disjoint_family_on_def)
ultimately show "(\<Sum>i. measure M' (A i)) = measure M' (\<Union>i. A i)"
using measure_countably_additive[OF _ **] A T
by (auto simp: comp_def vimage_UN measure_preserving_def)
qed
qed
qed
lemma (in measure_space) almost_everywhere_vimage:
assumes T: "sigma_algebra M'" "T \<in> measure_preserving M M'"
and AE: "measure_space.almost_everywhere M' P"
shows "AE x. P (T x)"
proof -
interpret M': measure_space M' using T by (rule measure_space_vimage)
from AE[THEN M'.AE_E] guess N .
then show ?thesis
unfolding almost_everywhere_def M'.almost_everywhere_def
using T(2) unfolding measurable_def measure_preserving_def
by (intro bexI[of _ "T -` N \<inter> space M"]) auto
qed
lemma measure_unique_Int_stable_vimage:
fixes A :: "nat \<Rightarrow> 'a set"
assumes E: "Int_stable E"
and A: "range A \<subseteq> sets E" "incseq A" "(\<Union>i. A i) = space E" "\<And>i. measure M (A i) \<noteq> \<infinity>"
and N: "measure_space N" "T \<in> measurable N M"
and M: "measure_space M" "sets (sigma E) = sets M" "space E = space M"
and eq: "\<And>X. X \<in> sets E \<Longrightarrow> measure M X = measure N (T -` X \<inter> space N)"
assumes X: "X \<in> sets (sigma E)"
shows "measure M X = measure N (T -` X \<inter> space N)"
proof (rule measure_unique_Int_stable[OF E A(1,2,3) _ _ eq _ X])
interpret M: measure_space M by fact
interpret N: measure_space N by fact
let "?T X" = "T -` X \<inter> space N"
show "measure_space \<lparr>space = space E, sets = sets (sigma E), measure = measure M\<rparr>"
by (rule M.measure_space_cong) (auto simp: M)
show "measure_space \<lparr>space = space E, sets = sets (sigma E), measure = \<lambda>X. measure N (?T X)\<rparr>" (is "measure_space ?E")
proof (rule N.measure_space_vimage)
show "sigma_algebra ?E"
by (rule M.sigma_algebra_cong) (auto simp: M)
show "T \<in> measure_preserving N ?E"
using `T \<in> measurable N M` by (auto simp: M measurable_def measure_preserving_def)
qed
show "\<And>i. M.\<mu> (A i) \<noteq> \<infinity>" by fact
qed
lemma (in measure_space) measure_preserving_Int_stable:
fixes A :: "nat \<Rightarrow> 'a set"
assumes E: "Int_stable E" "range A \<subseteq> sets E" "incseq A" "(\<Union>i. A i) = space E" "\<And>i. measure E (A i) \<noteq> \<infinity>"
and N: "measure_space (sigma E)"
and T: "T \<in> measure_preserving M E"
shows "T \<in> measure_preserving M (sigma E)"
proof
interpret E: measure_space "sigma E" by fact
show "T \<in> measurable M (sigma E)"
using T E.sets_into_space
by (intro measurable_sigma) (auto simp: measure_preserving_def measurable_def)
fix X assume "X \<in> sets (sigma E)"
show "\<mu> (T -` X \<inter> space M) = E.\<mu> X"
proof (rule measure_unique_Int_stable_vimage[symmetric])
show "sets (sigma E) = sets (sigma E)" "space E = space (sigma E)"
"\<And>i. E.\<mu> (A i) \<noteq> \<infinity>" using E by auto
show "measure_space M" by default
next
fix X assume "X \<in> sets E" then show "E.\<mu> X = \<mu> (T -` X \<inter> space M)"
using T unfolding measure_preserving_def by auto
qed fact+
qed
section "Real measure values"
lemma (in measure_space) real_measure_Union:
assumes finite: "\<mu> A \<noteq> \<infinity>" "\<mu> B \<noteq> \<infinity>"
and measurable: "A \<in> sets M" "B \<in> sets M" "A \<inter> B = {}"
shows "real (\<mu> (A \<union> B)) = real (\<mu> A) + real (\<mu> B)"
unfolding measure_additive[symmetric, OF measurable]
using measurable(1,2)[THEN positive_measure]
using finite by (cases rule: extreal2_cases[of "\<mu> A" "\<mu> B"]) auto
lemma (in measure_space) real_measure_finite_Union:
assumes measurable:
"finite S" "\<And>i. i \<in> S \<Longrightarrow> A i \<in> sets M" "disjoint_family_on A S"
assumes finite: "\<And>i. i \<in> S \<Longrightarrow> \<mu> (A i) \<noteq> \<infinity>"
shows "real (\<mu> (\<Union>i\<in>S. A i)) = (\<Sum>i\<in>S. real (\<mu> (A i)))"
using finite measurable(2)[THEN positive_measure]
by (force intro!: setsum_real_of_extreal[symmetric]
simp: measure_setsum[OF measurable, symmetric])
lemma (in measure_space) real_measure_Diff:
assumes finite: "\<mu> A \<noteq> \<infinity>"
and measurable: "A \<in> sets M" "B \<in> sets M" "B \<subseteq> A"
shows "real (\<mu> (A - B)) = real (\<mu> A) - real (\<mu> B)"
proof -
have "\<mu> (A - B) \<le> \<mu> A" "\<mu> B \<le> \<mu> A"
using measurable by (auto intro!: measure_mono)
hence "real (\<mu> ((A - B) \<union> B)) = real (\<mu> (A - B)) + real (\<mu> B)"
using measurable finite by (rule_tac real_measure_Union) auto
thus ?thesis using `B \<subseteq> A` by (auto simp: Un_absorb2)
qed
lemma (in measure_space) real_measure_UNION:
assumes measurable: "range A \<subseteq> sets M" "disjoint_family A"
assumes finite: "\<mu> (\<Union>i. A i) \<noteq> \<infinity>"
shows "(\<lambda>i. real (\<mu> (A i))) sums (real (\<mu> (\<Union>i. A i)))"
proof -
have "\<And>i. 0 \<le> \<mu> (A i)" using measurable by auto
with summable_sums[OF summable_extreal_pos, of "\<lambda>i. \<mu> (A i)"]
measure_countably_additive[OF measurable]
have "(\<lambda>i. \<mu> (A i)) sums (\<mu> (\<Union>i. A i))" by simp
moreover
{ fix i
have "\<mu> (A i) \<le> \<mu> (\<Union>i. A i)"
using measurable by (auto intro!: measure_mono)
moreover have "0 \<le> \<mu> (A i)" using measurable by auto
ultimately have "\<mu> (A i) = extreal (real (\<mu> (A i)))"
using finite by (cases "\<mu> (A i)") auto }
moreover
have "0 \<le> \<mu> (\<Union>i. A i)" using measurable by auto
then have "\<mu> (\<Union>i. A i) = extreal (real (\<mu> (\<Union>i. A i)))"
using finite by (cases "\<mu> (\<Union>i. A i)") auto
ultimately show ?thesis
unfolding sums_extreal[symmetric] by simp
qed
lemma (in measure_space) real_measure_subadditive:
assumes measurable: "A \<in> sets M" "B \<in> sets M"
and fin: "\<mu> A \<noteq> \<infinity>" "\<mu> B \<noteq> \<infinity>"
shows "real (\<mu> (A \<union> B)) \<le> real (\<mu> A) + real (\<mu> B)"
proof -
have "0 \<le> \<mu> (A \<union> B)" using measurable by auto
then show "real (\<mu> (A \<union> B)) \<le> real (\<mu> A) + real (\<mu> B)"
using measure_subadditive[OF measurable] fin
by (cases rule: extreal3_cases[of "\<mu> (A \<union> B)" "\<mu> A" "\<mu> B"]) auto
qed
lemma (in measure_space) real_measure_setsum_singleton:
assumes S: "finite S" "\<And>x. x \<in> S \<Longrightarrow> {x} \<in> sets M"
and fin: "\<And>x. x \<in> S \<Longrightarrow> \<mu> {x} \<noteq> \<infinity>"
shows "real (\<mu> S) = (\<Sum>x\<in>S. real (\<mu> {x}))"
using measure_finite_singleton[OF S] fin
using positive_measure[OF S(2)]
by (force intro!: setsum_real_of_extreal[symmetric])
lemma (in measure_space) real_continuity_from_below:
assumes A: "range A \<subseteq> sets M" "incseq A" and fin: "\<mu> (\<Union>i. A i) \<noteq> \<infinity>"
shows "(\<lambda>i. real (\<mu> (A i))) ----> real (\<mu> (\<Union>i. A i))"
proof -
have "0 \<le> \<mu> (\<Union>i. A i)" using A by auto
then have "extreal (real (\<mu> (\<Union>i. A i))) = \<mu> (\<Union>i. A i)"
using fin by (auto intro: extreal_real')
then show ?thesis
using continuity_from_below_Lim[OF A]
by (intro lim_real_of_extreal) simp
qed
lemma (in measure_space) continuity_from_above_Lim:
assumes A: "range A \<subseteq> sets M" "decseq A" and fin: "\<And>i. \<mu> (A i) \<noteq> \<infinity>"
shows "(\<lambda>i. (\<mu> (A i))) ----> \<mu> (\<Inter>i. A i)"
using LIMSEQ_extreal_INFI[OF measure_decseq, OF A]
using continuity_from_above[OF A fin] by simp
lemma (in measure_space) real_continuity_from_above:
assumes A: "range A \<subseteq> sets M" "decseq A" and fin: "\<And>i. \<mu> (A i) \<noteq> \<infinity>"
shows "(\<lambda>n. real (\<mu> (A n))) ----> real (\<mu> (\<Inter>i. A i))"
proof -
have "0 \<le> \<mu> (\<Inter>i. A i)" using A by auto
moreover
have "\<mu> (\<Inter>i. A i) \<le> \<mu> (A 0)"
using A by (auto intro!: measure_mono)
ultimately have "extreal (real (\<mu> (\<Inter>i. A i))) = \<mu> (\<Inter>i. A i)"
using fin by (auto intro: extreal_real')
then show ?thesis
using continuity_from_above_Lim[OF A fin]
by (intro lim_real_of_extreal) simp
qed
lemma (in measure_space) real_measure_countably_subadditive:
assumes A: "range A \<subseteq> sets M" and fin: "(\<Sum>i. \<mu> (A i)) \<noteq> \<infinity>"
shows "real (\<mu> (\<Union>i. A i)) \<le> (\<Sum>i. real (\<mu> (A i)))"
proof -
{ fix i
have "0 \<le> \<mu> (A i)" using A by auto
moreover have "\<mu> (A i) \<noteq> \<infinity>" using A by (intro suminf_PInfty[OF _ fin]) auto
ultimately have "\<bar>\<mu> (A i)\<bar> \<noteq> \<infinity>" by auto }
moreover have "0 \<le> \<mu> (\<Union>i. A i)" using A by auto
ultimately have "extreal (real (\<mu> (\<Union>i. A i))) \<le> (\<Sum>i. extreal (real (\<mu> (A i))))"
using measure_countably_subadditive[OF A] by (auto simp: extreal_real)
also have "\<dots> = extreal (\<Sum>i. real (\<mu> (A i)))"
using A
by (auto intro!: sums_unique[symmetric] sums_extreal[THEN iffD2] summable_sums summable_real_of_extreal fin)
finally show ?thesis by simp
qed
locale finite_measure = measure_space +
assumes finite_measure_of_space: "\<mu> (space M) \<noteq> \<infinity>"
sublocale finite_measure < sigma_finite_measure
proof
show "\<exists>A. range A \<subseteq> sets M \<and> (\<Union>i. A i) = space M \<and> (\<forall>i. \<mu> (A i) \<noteq> \<infinity>)"
using finite_measure_of_space by (auto intro!: exI[of _ "\<lambda>x. space M"])
qed
lemma (in finite_measure) finite_measure[simp, intro]:
assumes "A \<in> sets M"
shows "\<mu> A \<noteq> \<infinity>"
proof -
from `A \<in> sets M` have "A \<subseteq> space M"
using sets_into_space by blast
then have "\<mu> A \<le> \<mu> (space M)"
using assms top by (rule measure_mono)
then show ?thesis
using finite_measure_of_space by auto
qed
lemma (in finite_measure) measure_not_inf:
assumes A: "A \<in> sets M"
shows "\<bar>\<mu> A\<bar> \<noteq> \<infinity>"
using finite_measure[OF A] positive_measure[OF A] by auto
definition (in finite_measure)
"\<mu>' A = (if A \<in> sets M then real (\<mu> A) else 0)"
lemma (in finite_measure) finite_measure_eq: "A \<in> sets M \<Longrightarrow> \<mu> A = extreal (\<mu>' A)"
using measure_not_inf[of A] by (auto simp: \<mu>'_def)
lemma (in finite_measure) positive_measure': "0 \<le> \<mu>' A"
unfolding \<mu>'_def by (auto simp: real_of_extreal_pos)
lemma (in finite_measure) bounded_measure: "\<mu>' A \<le> \<mu>' (space M)"
proof cases
assume "A \<in> sets M"
moreover then have "\<mu> A \<le> \<mu> (space M)"
using sets_into_space by (auto intro!: measure_mono)
ultimately show ?thesis
using measure_not_inf[of A] measure_not_inf[of "space M"]
by (auto simp: \<mu>'_def)
qed (simp add: \<mu>'_def real_of_extreal_pos)
lemma (in finite_measure) restricted_finite_measure:
assumes "S \<in> sets M"
shows "finite_measure (restricted_space S)"
(is "finite_measure ?r")
unfolding finite_measure_def finite_measure_axioms_def
proof (intro conjI)
show "measure_space ?r" using restricted_measure_space[OF assms] .
next
show "measure ?r (space ?r) \<noteq> \<infinity>" using finite_measure[OF `S \<in> sets M`] by auto
qed
lemma (in measure_space) restricted_to_finite_measure:
assumes "S \<in> sets M" "\<mu> S \<noteq> \<infinity>"
shows "finite_measure (restricted_space S)"
proof -
have "measure_space (restricted_space S)"
using `S \<in> sets M` by (rule restricted_measure_space)
then show ?thesis
unfolding finite_measure_def finite_measure_axioms_def
using assms by auto
qed
lemma (in finite_measure) finite_measure_Diff:
assumes sets: "A \<in> sets M" "B \<in> sets M" and "B \<subseteq> A"
shows "\<mu>' (A - B) = \<mu>' A - \<mu>' B"
using sets[THEN finite_measure_eq]
using Diff[OF sets, THEN finite_measure_eq]
using measure_Diff[OF _ assms] by simp
lemma (in finite_measure) finite_measure_Union:
assumes sets: "A \<in> sets M" "B \<in> sets M" and "A \<inter> B = {}"
shows "\<mu>' (A \<union> B) = \<mu>' A + \<mu>' B"
using measure_additive[OF assms]
using sets[THEN finite_measure_eq]
using Un[OF sets, THEN finite_measure_eq]
by simp
lemma (in finite_measure) finite_measure_finite_Union:
assumes S: "finite S" "\<And>i. i \<in> S \<Longrightarrow> A i \<in> sets M"
and dis: "disjoint_family_on A S"
shows "\<mu>' (\<Union>i\<in>S. A i) = (\<Sum>i\<in>S. \<mu>' (A i))"
using measure_setsum[OF assms]
using finite_UN[of S A, OF S, THEN finite_measure_eq]
using S(2)[THEN finite_measure_eq]
by simp
lemma (in finite_measure) finite_measure_UNION:
assumes A: "range A \<subseteq> sets M" "disjoint_family A"
shows "(\<lambda>i. \<mu>' (A i)) sums (\<mu>' (\<Union>i. A i))"
using real_measure_UNION[OF A]
using countable_UN[OF A(1), THEN finite_measure_eq]
using A(1)[THEN subsetD, THEN finite_measure_eq]
by auto
lemma (in finite_measure) finite_measure_mono:
assumes B: "B \<in> sets M" and "A \<subseteq> B" shows "\<mu>' A \<le> \<mu>' B"
proof cases
assume "A \<in> sets M"
from this[THEN finite_measure_eq] B[THEN finite_measure_eq]
show ?thesis using measure_mono[OF `A \<subseteq> B` `A \<in> sets M` `B \<in> sets M`] by simp
next
assume "A \<notin> sets M" then show ?thesis
using positive_measure'[of B] unfolding \<mu>'_def by auto
qed
lemma (in finite_measure) finite_measure_subadditive:
assumes m: "A \<in> sets M" "B \<in> sets M"
shows "\<mu>' (A \<union> B) \<le> \<mu>' A + \<mu>' B"
using measure_subadditive[OF m]
using m[THEN finite_measure_eq] Un[OF m, THEN finite_measure_eq] by simp
lemma (in finite_measure) finite_measure_countably_subadditive:
assumes A: "range A \<subseteq> sets M" and sum: "summable (\<lambda>i. \<mu>' (A i))"
shows "\<mu>' (\<Union>i. A i) \<le> (\<Sum>i. \<mu>' (A i))"
proof -
note A[THEN subsetD, THEN finite_measure_eq, simp]
note countable_UN[OF A, THEN finite_measure_eq, simp]
from `summable (\<lambda>i. \<mu>' (A i))`
have "(\<lambda>i. extreal (\<mu>' (A i))) sums extreal (\<Sum>i. \<mu>' (A i))"
by (simp add: sums_extreal) (rule summable_sums)
from sums_unique[OF this, symmetric]
measure_countably_subadditive[OF A]
show ?thesis by simp
qed
lemma (in finite_measure) finite_measure_finite_singleton:
assumes "finite S" and *: "\<And>x. x \<in> S \<Longrightarrow> {x} \<in> sets M"
shows "\<mu>' S = (\<Sum>x\<in>S. \<mu>' {x})"
using real_measure_setsum_singleton[OF assms]
using *[THEN finite_measure_eq]
using finite_UN[of S "\<lambda>x. {x}", OF assms, THEN finite_measure_eq]
by simp
lemma (in finite_measure) finite_continuity_from_below:
assumes A: "range A \<subseteq> sets M" and "incseq A"
shows "(\<lambda>i. \<mu>' (A i)) ----> \<mu>' (\<Union>i. A i)"
using real_continuity_from_below[OF A, OF `incseq A` finite_measure] assms
using A[THEN subsetD, THEN finite_measure_eq]
using countable_UN[OF A, THEN finite_measure_eq]
by auto
lemma (in finite_measure) finite_continuity_from_above:
assumes A: "range A \<subseteq> sets M" and "decseq A"
shows "(\<lambda>n. \<mu>' (A n)) ----> \<mu>' (\<Inter>i. A i)"
using real_continuity_from_above[OF A, OF `decseq A` finite_measure] assms
using A[THEN subsetD, THEN finite_measure_eq]
using countable_INT[OF A, THEN finite_measure_eq]
by auto
lemma (in finite_measure) finite_measure_compl:
assumes S: "S \<in> sets M"
shows "\<mu>' (space M - S) = \<mu>' (space M) - \<mu>' S"
using measure_compl[OF S, OF finite_measure, OF S]
using S[THEN finite_measure_eq]
using compl_sets[OF S, THEN finite_measure_eq]
using top[THEN finite_measure_eq]
by simp
lemma (in finite_measure) finite_measure_inter_full_set:
assumes S: "S \<in> sets M" "T \<in> sets M"
assumes T: "\<mu>' T = \<mu>' (space M)"
shows "\<mu>' (S \<inter> T) = \<mu>' S"
using measure_inter_full_set[OF S finite_measure]
using T Diff[OF S(2,1)] Diff[OF S, THEN finite_measure_eq]
using Int[OF S, THEN finite_measure_eq]
using S[THEN finite_measure_eq] top[THEN finite_measure_eq]
by simp
lemma (in finite_measure) empty_measure'[simp]: "\<mu>' {} = 0"
unfolding \<mu>'_def by simp
section "Finite spaces"
locale finite_measure_space = measure_space + finite_sigma_algebra +
assumes finite_single_measure[simp]: "\<And>x. x \<in> space M \<Longrightarrow> \<mu> {x} \<noteq> \<infinity>"
lemma (in finite_measure_space) sum_over_space: "(\<Sum>x\<in>space M. \<mu> {x}) = \<mu> (space M)"
using measure_setsum[of "space M" "\<lambda>i. {i}"]
by (simp add: sets_eq_Pow disjoint_family_on_def finite_space)
lemma finite_measure_spaceI:
assumes "finite (space M)" "sets M = Pow(space M)" and space: "measure M (space M) \<noteq> \<infinity>"
and add: "\<And>A B. A\<subseteq>space M \<Longrightarrow> B\<subseteq>space M \<Longrightarrow> A \<inter> B = {} \<Longrightarrow> measure M (A \<union> B) = measure M A + measure M B"
and "measure M {} = 0" "\<And>A. A \<subseteq> space M \<Longrightarrow> 0 \<le> measure M A"
shows "finite_measure_space M"
unfolding finite_measure_space_def finite_measure_space_axioms_def
proof (intro allI impI conjI)
show "measure_space M"
proof (rule finite_additivity_sufficient)
have *: "\<lparr>space = space M, sets = Pow (space M), \<dots> = algebra.more M\<rparr> = M"
unfolding assms(2)[symmetric] by (auto intro!: algebra.equality)
show "sigma_algebra M"
using sigma_algebra_Pow[of "space M" "algebra.more M"]
unfolding * .
show "finite (space M)" by fact
show "positive M (measure M)" unfolding positive_def using assms by auto
show "additive M (measure M)" unfolding additive_def using assms by simp
qed
then interpret measure_space M .
show "finite_sigma_algebra M"
proof
show "finite (space M)" by fact
show "sets M = Pow (space M)" using assms by auto
qed
{ fix x assume *: "x \<in> space M"
with add[of "{x}" "space M - {x}"] space
show "\<mu> {x} \<noteq> \<infinity>" by (auto simp: insert_absorb[OF *] Diff_subset) }
qed
sublocale finite_measure_space \<subseteq> finite_measure
proof
show "\<mu> (space M) \<noteq> \<infinity>"
unfolding sum_over_space[symmetric] setsum_Pinfty
using finite_space finite_single_measure by auto
qed
lemma finite_measure_space_iff:
"finite_measure_space M \<longleftrightarrow>
finite (space M) \<and> sets M = Pow(space M) \<and> measure M (space M) \<noteq> \<infinity> \<and>
measure M {} = 0 \<and> (\<forall>A\<subseteq>space M. 0 \<le> measure M A) \<and>
(\<forall>A\<subseteq>space M. \<forall>B\<subseteq>space M. A \<inter> B = {} \<longrightarrow> measure M (A \<union> B) = measure M A + measure M B)"
(is "_ = ?rhs")
proof (intro iffI)
assume "finite_measure_space M"
then interpret finite_measure_space M .
show ?rhs
using finite_space sets_eq_Pow measure_additive empty_measure finite_measure
by auto
next
assume ?rhs then show "finite_measure_space M"
by (auto intro!: finite_measure_spaceI)
qed
lemma (in finite_measure_space) finite_measure_singleton:
assumes A: "A \<subseteq> space M" shows "\<mu>' A = (\<Sum>x\<in>A. \<mu>' {x})"
using A finite_subset[OF A finite_space]
by (intro finite_measure_finite_singleton) auto
lemma suminf_cmult_indicator:
fixes f :: "nat \<Rightarrow> extreal"
assumes "disjoint_family A" "x \<in> A i" "\<And>i. 0 \<le> f i"
shows "(\<Sum>n. f n * indicator (A n) x) = f i"
proof -
have **: "\<And>n. f n * indicator (A n) x = (if n = i then f n else 0 :: extreal)"
using `x \<in> A i` assms unfolding disjoint_family_on_def indicator_def by auto
then have "\<And>n. (\<Sum>j<n. f j * indicator (A j) x) = (if i < n then f i else 0 :: extreal)"
by (auto simp: setsum_cases)
moreover have "(SUP n. if i < n then f i else 0) = (f i :: extreal)"
proof (rule extreal_SUPI)
fix y :: extreal assume "\<And>n. n \<in> UNIV \<Longrightarrow> (if i < n then f i else 0) \<le> y"
from this[of "Suc i"] show "f i \<le> y" by auto
qed (insert assms, simp)
ultimately show ?thesis using assms
by (subst suminf_extreal_eq_SUPR) (auto simp: indicator_def)
qed
lemma suminf_indicator:
assumes "disjoint_family A"
shows "(\<Sum>n. indicator (A n) x :: extreal) = indicator (\<Union>i. A i) x"
proof cases
assume *: "x \<in> (\<Union>i. A i)"
then obtain i where "x \<in> A i" by auto
from suminf_cmult_indicator[OF assms(1), OF `x \<in> A i`, of "\<lambda>k. 1"]
show ?thesis using * by simp
qed simp
end