(* Author: Sébastien Gouëzel sebastien.gouezel@univ-rennes1.fr
License: BSD
*)
theory Essential_Supremum
imports "../Analysis/Analysis"
begin
section {*The essential supremum*}
text {*In this paragraph, we define the essential supremum and give its basic properties. The
essential supremum of a function is its maximum value if one is allowed to throw away a set
of measure $0$. It is convenient to define it to be infinity for non-measurable functions, as
it allows for neater statements in general. This is a prerequisiste to define the space $L^\infty$.*}
definition esssup::"'a measure \<Rightarrow> ('a \<Rightarrow> ereal) \<Rightarrow> ereal"
where "esssup M f = (if f \<in> borel_measurable M then Inf {z. emeasure M {x \<in> space M. f x > z} = 0} else \<infinity>)"
lemma esssup_zero_measure:
"emeasure M {x \<in> space M. f x > esssup M f} = 0"
proof (cases "esssup M f = \<infinity>")
case True
then show ?thesis by auto
next
case False
then have [measurable]: "f \<in> borel_measurable M" unfolding esssup_def by meson
have "esssup M f < \<infinity>" using False by auto
have *: "{x \<in> space M. f x > z} \<in> null_sets M" if "z > esssup M f" for z
proof -
have "\<exists>w. w < z \<and> emeasure M {x \<in> space M. f x > w} = 0"
using `z > esssup M f` unfolding esssup_def apply auto
by (metis (mono_tags, lifting) Inf_less_iff mem_Collect_eq)
then obtain w where "w < z" "emeasure M {x \<in> space M. f x > w} = 0" by auto
then have a: "{x \<in> space M. f x > w} \<in> null_sets M" by auto
have b: "{x \<in> space M. f x > z} \<subseteq> {x \<in> space M. f x > w}" using `w < z` by auto
show ?thesis using null_sets_subset[OF a _ b] by simp
qed
obtain u::"nat \<Rightarrow> ereal" where u: "\<And>n. u n > esssup M f" "u \<longlonglongrightarrow> esssup M f"
using approx_from_above_dense_linorder[OF `esssup M f < \<infinity>`] by auto
have "{x \<in> space M. f x > esssup M f} = (\<Union>n. {x \<in> space M. f x > u n})"
using u apply auto
apply (metis (mono_tags, lifting) order_tendsto_iff eventually_mono LIMSEQ_unique)
using less_imp_le less_le_trans by blast
also have "... \<in> null_sets M"
using *[OF u(1)] by auto
finally show ?thesis by auto
qed
lemma esssup_AE:
"AE x in M. f x \<le> esssup M f"
proof (cases "f \<in> borel_measurable M")
case True
show ?thesis
apply (rule AE_I[OF _ esssup_zero_measure[of _ f]]) using True by auto
next
case False
then have "esssup M f = \<infinity>" unfolding esssup_def by auto
then show ?thesis by auto
qed
lemma esssup_pos_measure:
assumes "f \<in> borel_measurable M" "z < esssup M f"
shows "emeasure M {x \<in> space M. f x > z} > 0"
using assms Inf_less_iff mem_Collect_eq not_gr_zero unfolding esssup_def by force
lemma esssup_non_measurable:
assumes "f \<notin> borel_measurable M"
shows "esssup M f = \<infinity>"
using assms unfolding esssup_def by auto
lemma esssup_I [intro]:
assumes "f \<in> borel_measurable M" "AE x in M. f x \<le> c"
shows "esssup M f \<le> c"
proof -
have "emeasure M {x \<in> space M. \<not> f x \<le> c} = 0"
apply (rule AE_E2[OF assms(2)]) using assms(1) by simp
then have *: "emeasure M {x \<in> space M. f x > c} = 0"
by (metis (mono_tags, lifting) Collect_cong not_less)
show ?thesis unfolding esssup_def using assms apply simp by (rule Inf_lower, simp add: *)
qed
lemma esssup_AE_mono:
assumes "f \<in> borel_measurable M" "AE x in M. f x \<le> g x"
shows "esssup M f \<le> esssup M g"
proof (cases "g \<in> borel_measurable M")
case False
then show ?thesis unfolding esssup_def by auto
next
case True
have "AE x in M. f x \<le> esssup M g"
using assms(2) esssup_AE[of g M] by auto
then show ?thesis using esssup_I assms(1) by auto
qed
lemma esssup_mono:
assumes "f \<in> borel_measurable M" "\<And>x. f x \<le> g x"
shows "esssup M f \<le> esssup M g"
apply (rule esssup_AE_mono) using assms by auto
lemma esssup_AE_cong:
assumes [measurable]: "f \<in> borel_measurable M" "g \<in> borel_measurable M"
and "AE x in M. f x = g x"
shows "esssup M f = esssup M g"
proof -
have "esssup M f \<le> esssup M g"
using esssup_AE_mono[OF assms(1), of g] assms(3) by (simp add: eq_iff)
moreover have "esssup M g \<le> esssup M f"
using esssup_AE_mono[OF assms(2), of f] assms(3) by (simp add: eq_iff)
ultimately show ?thesis by simp
qed
lemma esssup_const:
assumes "emeasure M (space M) \<noteq> 0"
shows "esssup M (\<lambda>x. c) = c"
proof -
have "emeasure M {x \<in> space M. (\<lambda>x. c) x > z} = (if c > z then emeasure M (space M) else 0)" for z
by auto
then have "{z. emeasure M {x \<in> space M. (\<lambda>x. c) x > z} = 0} = {c..}" using assms by auto
then have "esssup M (\<lambda>x. c) = Inf {c..}" unfolding esssup_def by auto
then show ?thesis by auto
qed
lemma esssup_cmult:
assumes "c > (0::real)"
shows "esssup M (\<lambda>x. c * f x) = c * esssup M f"
proof (cases "f \<in> borel_measurable M")
case True
then have a [measurable]: "f \<in> borel_measurable M" by simp
then have b [measurable]: "(\<lambda>x. c * f x) \<in> borel_measurable M" by simp
have a: "{x \<in> space M. c * z < c * f x} = {x \<in> space M. z < f x}" for z::ereal
by (meson assms ereal_less(2) ereal_mult_left_mono ereal_mult_strict_left_mono less_ereal.simps(4) less_imp_le not_less)
have *: "{z::ereal. emeasure M {x \<in> space M. ereal c * f x > z} = 0} = {c * z| z::ereal. emeasure M {x \<in> space M. f x > z} = 0}"
proof (auto)
fix y assume *: "emeasure M {x \<in> space M. y < c * f x} = 0"
define z where "z = y / c"
have **: "y = c * z" unfolding z_def using assms by (simp add: ereal_mult_divide)
then have "y = c * z \<and> emeasure M {x \<in> space M. z < f x} = 0"
using * unfolding ** unfolding a by auto
then show "\<exists>z. y = ereal c * z \<and> emeasure M {x \<in> space M. z < f x} = 0"
by auto
next
fix z assume *: "emeasure M {x \<in> space M. z < f x} = 0"
then show "emeasure M {x \<in> space M. c * z < c * f x} = 0"
using a by auto
qed
have "esssup M (\<lambda>x. c * f x) = Inf {z::ereal. emeasure M {x \<in> space M. c * f x > z} = 0}"
unfolding esssup_def using b by auto
also have "... = Inf {c * z| z::ereal. emeasure M {x \<in> space M. f x > z} = 0}"
using * by auto
also have "... = ereal c * Inf {z. emeasure M {x \<in> space M. f x > z} = 0}"
apply (rule ereal_Inf_cmult) using assms by auto
also have "... = c * esssup M f"
unfolding esssup_def by auto
finally show ?thesis by simp
next
case False
have "esssup M f = \<infinity>" using False unfolding esssup_def by auto
then have *: "c * esssup M f = \<infinity>" using assms by (simp add: ennreal_mult_eq_top_iff)
have "(\<lambda>x. c * f x) \<notin> borel_measurable M"
proof (rule ccontr)
assume "\<not> (\<lambda>x. c * f x) \<notin> borel_measurable M"
then have [measurable]: "(\<lambda>x. c * f x) \<in> borel_measurable M" by simp
then have "(\<lambda>x. (1/c) * (c * f x)) \<in> borel_measurable M" by measurable
moreover have "(1/c) * (c * f x) = f x" for x
by (metis "*" PInfty_neq_ereal(1) divide_inverse divide_self_if ereal_zero_mult mult.assoc mult.commute mult.left_neutral one_ereal_def times_ereal.simps(1) zero_ereal_def)
ultimately show False using False by auto
qed
then have "esssup M (\<lambda>x. c * f x) = \<infinity>" unfolding esssup_def by simp
then show ?thesis using * by auto
qed
lemma esssup_add:
"esssup M (\<lambda>x. f x + g x) \<le> esssup M f + esssup M g"
proof (cases "f \<in> borel_measurable M \<and> g \<in> borel_measurable M")
case True
then have [measurable]: "(\<lambda>x. f x + g x) \<in> borel_measurable M" by auto
have "f x + g x \<le> esssup M f + esssup M g" if "f x \<le> esssup M f" "g x \<le> esssup M g" for x
using that ereal_add_mono by auto
then have "AE x in M. f x + g x \<le> esssup M f + esssup M g"
using esssup_AE[of f M] esssup_AE[of g M] by auto
then show ?thesis using esssup_I by auto
next
case False
then have "esssup M f + esssup M g = \<infinity>" unfolding esssup_def by auto
then show ?thesis by auto
qed
lemma esssup_zero_space:
assumes "emeasure M (space M) = 0"
"f \<in> borel_measurable M"
shows "esssup M f = - \<infinity>"
proof -
have "emeasure M {x \<in> space M. f x > - \<infinity>} = 0"
using assms(1) emeasure_mono emeasure_eq_0 by fastforce
then show ?thesis unfolding esssup_def using assms(2) Inf_eq_MInfty by auto
qed
end