Theory HOL-Analysis.Continuous_Extension
section ‹Continuous Extensions of Functions›
theory Continuous_Extension
imports Starlike
begin
subsection‹Partitions of unity subordinate to locally finite open coverings›
text‹A difference from HOL Light: all summations over infinite sets equal zero,
so the "support" must be made explicit in the summation below!›
proposition subordinate_partition_of_unity:
fixes S :: "'a::metric_space set"
assumes "S ⊆ ⋃𝒞" and opC: "⋀T. T ∈ 𝒞 ⟹ open T"
and fin: "⋀x. x ∈ S ⟹ ∃V. open V ∧ x ∈ V ∧ finite {U ∈ 𝒞. U ∩ V ≠ {}}"
obtains F :: "['a set, 'a] ⇒ real"
where "⋀U. U ∈ 𝒞 ⟹ continuous_on S (F U) ∧ (∀x ∈ S. 0 ≤ F U x)"
and "⋀x U. ⟦U ∈ 𝒞; x ∈ S; x ∉ U⟧ ⟹ F U x = 0"
and "⋀x. x ∈ S ⟹ supp_sum (λW. F W x) 𝒞 = 1"
and "⋀x. x ∈ S ⟹ ∃V. open V ∧ x ∈ V ∧ finite {U ∈ 𝒞. ∃x∈V. F U x ≠ 0}"
proof (cases "∃W. W ∈ 𝒞 ∧ S ⊆ W")
case True
then obtain W where "W ∈ 𝒞" "S ⊆ W" by metis
then show ?thesis
by (rule_tac F = "λV x. if V = W then 1 else 0" in that) (auto simp: supp_sum_def support_on_def)
next
case False
have nonneg: "0 ≤ supp_sum (λV. setdist {x} (S - V)) 𝒞" for x
by (simp add: supp_sum_def sum_nonneg)
have sd_pos: "0 < setdist {x} (S - V)" if "V ∈ 𝒞" "x ∈ S" "x ∈ V" for V x
proof -
have "closedin (top_of_set S) (S - V)"
by (simp add: Diff_Diff_Int closedin_def opC openin_open_Int ‹V ∈ 𝒞›)
with that False setdist_pos_le [of "{x}" "S - V"]
show ?thesis
using setdist_gt_0_closedin by fastforce
qed
have ss_pos: "0 < supp_sum (λV. setdist {x} (S - V)) 𝒞" if "x ∈ S" for x
proof -
obtain U where "U ∈ 𝒞" "x ∈ U" using ‹x ∈ S› ‹S ⊆ ⋃𝒞›
by blast
obtain V where "open V" "x ∈ V" "finite {U ∈ 𝒞. U ∩ V ≠ {}}"
using ‹x ∈ S› fin by blast
then have *: "finite {A ∈ 𝒞. ¬ S ⊆ A ∧ x ∉ closure (S - A)}"
using closure_def that by (blast intro: rev_finite_subset)
have "x ∉ closure (S - U)"
using ‹U ∈ 𝒞› ‹x ∈ U› opC open_Int_closure_eq_empty by fastforce
then show ?thesis
apply (simp add: setdist_eq_0_sing_1 supp_sum_def support_on_def)
apply (rule ordered_comm_monoid_add_class.sum_pos2 [OF *, of U])
using ‹U ∈ 𝒞› ‹x ∈ U› False
apply (auto simp: sd_pos that)
done
qed
define F where
"F ≡ λW x. if x ∈ S then setdist {x} (S - W) / supp_sum (λV. setdist {x} (S - V)) 𝒞 else 0"
show ?thesis
proof (rule_tac F = F in that)
have "continuous_on S (F U)" if "U ∈ 𝒞" for U
proof -
have *: "continuous_on S (λx. supp_sum (λV. setdist {x} (S - V)) 𝒞)"
proof (clarsimp simp add: continuous_on_eq_continuous_within)
fix x assume "x ∈ S"
then obtain X where "open X" and x: "x ∈ S ∩ X" and finX: "finite {U ∈ 𝒞. U ∩ X ≠ {}}"
using assms by blast
then have OSX: "openin (top_of_set S) (S ∩ X)" by blast
have sumeq: "⋀x. x ∈ S ∩ X ⟹
(∑V | V ∈ 𝒞 ∧ V ∩ X ≠ {}. setdist {x} (S - V))
= supp_sum (λV. setdist {x} (S - V)) 𝒞"
apply (simp add: supp_sum_def)
apply (rule sum.mono_neutral_right [OF finX])
apply (auto simp: setdist_eq_0_sing_1 support_on_def subset_iff)
apply (meson DiffI closure_subset disjoint_iff_not_equal subsetCE)
done
show "continuous (at x within S) (λx. supp_sum (λV. setdist {x} (S - V)) 𝒞)"
apply (rule continuous_transform_within_openin
[where f = "λx. (sum (λV. setdist {x} (S - V)) {V ∈ 𝒞. V ∩ X ≠ {}})"
and S ="S ∩ X"])
apply (rule continuous_intros continuous_at_setdist continuous_at_imp_continuous_at_within OSX x)+
apply (simp add: sumeq)
done
qed
show ?thesis
apply (simp add: F_def)
apply (rule continuous_intros *)+
using ss_pos apply force
done
qed
moreover have "⟦U ∈ 𝒞; x ∈ S⟧ ⟹ 0 ≤ F U x" for U x
using nonneg [of x] by (simp add: F_def field_split_simps)
ultimately show "⋀U. U ∈ 𝒞 ⟹ continuous_on S (F U) ∧ (∀x∈S. 0 ≤ F U x)"
by metis
next
show "⋀x U. ⟦U ∈ 𝒞; x ∈ S; x ∉ U⟧ ⟹ F U x = 0"
by (simp add: setdist_eq_0_sing_1 closure_def F_def)
next
show "supp_sum (λW. F W x) 𝒞 = 1" if "x ∈ S" for x
using that ss_pos [OF that]
by (simp add: F_def field_split_simps supp_sum_divide_distrib [symmetric])
next
show "∃V. open V ∧ x ∈ V ∧ finite {U ∈ 𝒞. ∃x∈V. F U x ≠ 0}" if "x ∈ S" for x
using fin [OF that] that
by (fastforce simp: setdist_eq_0_sing_1 closure_def F_def elim!: rev_finite_subset)
qed
qed
subsection‹Urysohn's Lemma for Euclidean Spaces›
text ‹For Euclidean spaces the proof is easy using distances.›
lemma Urysohn_both_ne:
assumes US: "closedin (top_of_set U) S"
and UT: "closedin (top_of_set U) T"
and "S ∩ T = {}" "S ≠ {}" "T ≠ {}" "a ≠ b"
obtains f :: "'a::euclidean_space ⇒ 'b::real_normed_vector"
where "continuous_on U f"
"⋀x. x ∈ U ⟹ f x ∈ closed_segment a b"
"⋀x. x ∈ U ⟹ (f x = a ⟷ x ∈ S)"
"⋀x. x ∈ U ⟹ (f x = b ⟷ x ∈ T)"
proof -
have S0: "⋀x. x ∈ U ⟹ setdist {x} S = 0 ⟷ x ∈ S"
using ‹S ≠ {}› US setdist_eq_0_closedin by auto
have T0: "⋀x. x ∈ U ⟹ setdist {x} T = 0 ⟷ x ∈ T"
using ‹T ≠ {}› UT setdist_eq_0_closedin by auto
have sdpos: "0 < setdist {x} S + setdist {x} T" if "x ∈ U" for x
proof -
have "¬ (setdist {x} S = 0 ∧ setdist {x} T = 0)"
using assms by (metis IntI empty_iff setdist_eq_0_closedin that)
then show ?thesis
by (metis add.left_neutral add.right_neutral add_pos_pos linorder_neqE_linordered_idom not_le setdist_pos_le)
qed
define f where "f ≡ λx. a + (setdist {x} S / (setdist {x} S + setdist {x} T)) *⇩R (b - a)"
show ?thesis
proof (rule_tac f = f in that)
show "continuous_on U f"
using sdpos unfolding f_def
by (intro continuous_intros | force)+
show "f x ∈ closed_segment a b" if "x ∈ U" for x
unfolding f_def
apply (simp add: closed_segment_def)
apply (rule_tac x="(setdist {x} S / (setdist {x} S + setdist {x} T))" in exI)
using sdpos that apply (simp add: algebra_simps)
done
show "⋀x. x ∈ U ⟹ (f x = a ⟷ x ∈ S)"
using S0 ‹a ≠ b› f_def sdpos by force
show "(f x = b ⟷ x ∈ T)" if "x ∈ U" for x
proof -
have "f x = b ⟷ (setdist {x} S / (setdist {x} S + setdist {x} T)) = 1"
unfolding f_def
by (metis add_diff_cancel_left' ‹a ≠ b› diff_add_cancel eq_iff_diff_eq_0 scaleR_cancel_right scaleR_one)
also have "... ⟷ setdist {x} T = 0 ∧ setdist {x} S ≠ 0"
using sdpos that
by (simp add: field_split_simps) linarith
also have "... ⟷ x ∈ T"
using ‹S ≠ {}› ‹T ≠ {}› ‹S ∩ T = {}› that
by (force simp: S0 T0)
finally show ?thesis .
qed
qed
qed
lemma Urysohn_local_strong_aux:
assumes US: "closedin (top_of_set U) S"
and UT: "closedin (top_of_set U) T"
and "S ∩ T = {}" "a ≠ b" "S ≠ {}"
obtains f :: "'a::euclidean_space ⇒ 'b::euclidean_space"
where "continuous_on U f"
"⋀x. x ∈ U ⟹ f x ∈ closed_segment a b"
"⋀x. x ∈ U ⟹ (f x = a ⟷ x ∈ S)"
"⋀x. x ∈ U ⟹ (f x = b ⟷ x ∈ T)"
proof (cases "T = {}")
case True show ?thesis
proof (cases "S = U")
case True with ‹T = {}› ‹a ≠ b› show ?thesis
by (rule_tac f = "λx. a" in that) (auto)
next
case False
with US closedin_subset obtain c where c: "c ∈ U" "c ∉ S"
by fastforce
obtain f where f: "continuous_on U f"
"⋀x. x ∈ U ⟹ f x ∈ closed_segment a (midpoint a b)"
"⋀x. x ∈ U ⟹ (f x = midpoint a b ⟷ x = c)"
"⋀x. x ∈ U ⟹ (f x = a ⟷ x ∈ S)"
apply (rule Urysohn_both_ne [of U S "{c}" a "midpoint a b"])
using c ‹S ≠ {}› assms apply simp_all
apply (metis midpoint_eq_endpoint)
done
show ?thesis
apply (rule_tac f=f in that)
using ‹S ≠ {}› ‹T = {}› f ‹a ≠ b›
apply simp_all
apply (metis (no_types) closed_segment_commute csegment_midpoint_subset midpoint_sym subset_iff)
apply (metis closed_segment_commute midpoint_sym notin_segment_midpoint)
done
qed
next
case False
show ?thesis
using Urysohn_both_ne [OF US UT ‹S ∩ T = {}› ‹S ≠ {}› ‹T ≠ {}› ‹a ≠ b›] that
by blast
qed
proposition Urysohn_local_strong:
assumes US: "closedin (top_of_set U) S"
and UT: "closedin (top_of_set U) T"
and "S ∩ T = {}" "a ≠ b"
obtains f :: "'a::euclidean_space ⇒ 'b::euclidean_space"
where "continuous_on U f"
"⋀x. x ∈ U ⟹ f x ∈ closed_segment a b"
"⋀x. x ∈ U ⟹ (f x = a ⟷ x ∈ S)"
"⋀x. x ∈ U ⟹ (f x = b ⟷ x ∈ T)"
proof (cases "S = {}")
case True show ?thesis
proof (cases "T = {}")
case True show ?thesis
proof (rule_tac f = "λx. midpoint a b" in that)
show "continuous_on U (λx. midpoint a b)"
by (intro continuous_intros)
show "midpoint a b ∈ closed_segment a b"
using csegment_midpoint_subset by blast
show "(midpoint a b = a) = (x ∈ S)" for x
using ‹S = {}› ‹a ≠ b› by simp
show "(midpoint a b = b) = (x ∈ T)" for x
using ‹T = {}› ‹a ≠ b› by simp
qed
next
case False
with Urysohn_local_strong_aux [OF UT US] assms show ?thesis
by (smt (verit) True closed_segment_commute inf_bot_right that)
qed
next
case False
with Urysohn_local_strong_aux [OF assms] show ?thesis
using that by blast
qed
lemma Urysohn_local:
assumes US: "closedin (top_of_set U) S"
and UT: "closedin (top_of_set U) T"
and "S ∩ T = {}"
obtains f :: "'a::euclidean_space ⇒ 'b::euclidean_space"
where "continuous_on U f"
"⋀x. x ∈ U ⟹ f x ∈ closed_segment a b"
"⋀x. x ∈ S ⟹ f x = a"
"⋀x. x ∈ T ⟹ f x = b"
proof (cases "a = b")
case True then show ?thesis
by (rule_tac f = "λx. b" in that) (auto)
next
case False
with Urysohn_local_strong [OF assms] show ?thesis
by (smt (verit) US UT closedin_imp_subset subset_eq that)
qed
lemma Urysohn_strong:
assumes US: "closed S"
and UT: "closed T"
and "S ∩ T = {}" "a ≠ b"
obtains f :: "'a::euclidean_space ⇒ 'b::euclidean_space"
where "continuous_on UNIV f"
"⋀x. f x ∈ closed_segment a b"
"⋀x. f x = a ⟷ x ∈ S"
"⋀x. f x = b ⟷ x ∈ T"
using assms by (auto intro: Urysohn_local_strong [of UNIV S T])
proposition Urysohn:
assumes US: "closed S"
and UT: "closed T"
and "S ∩ T = {}"
obtains f :: "'a::euclidean_space ⇒ 'b::euclidean_space"
where "continuous_on UNIV f"
"⋀x. f x ∈ closed_segment a b"
"⋀x. x ∈ S ⟹ f x = a"
"⋀x. x ∈ T ⟹ f x = b"
using assms by (auto intro: Urysohn_local [of UNIV S T a b])
subsection‹Dugundji's Extension Theorem and Tietze Variants›
text ‹See \<^cite>‹"dugundji"›.›
theorem Dugundji:
fixes f :: "'a::{metric_space,second_countable_topology} ⇒ 'b::real_inner"
assumes "convex C" "C ≠ {}"
and cloin: "closedin (top_of_set U) S"
and contf: "continuous_on S f" and "f ` S ⊆ C"
obtains g where "continuous_on U g" "g ` U ⊆ C"
"⋀x. x ∈ S ⟹ g x = f x"
proof (cases "S = {}")
case True show thesis
proof
show "continuous_on U (λx. SOME y. y ∈ C)"
by (rule continuous_intros)
show "(λx. SOME y. y ∈ C) ` U ⊆ C"
by (simp add: ‹C ≠ {}› image_subsetI some_in_eq)
qed (use True in auto)
next
case False
then have sd_pos: "⋀x. ⟦x ∈ U; x ∉ S⟧ ⟹ 0 < setdist {x} S"
using setdist_eq_0_closedin [OF cloin] le_less setdist_pos_le by fastforce
define ℬ where "ℬ = {ball x (setdist {x} S / 2) |x. x ∈ U - S}"
have [simp]: "⋀T. T ∈ ℬ ⟹ open T"
by (auto simp: ℬ_def)
have USS: "U - S ⊆ ⋃ℬ"
by (auto simp: sd_pos ℬ_def)
obtain 𝒞 where USsub: "U - S ⊆ ⋃𝒞"
and nbrhd: "⋀U. U ∈ 𝒞 ⟹ open U ∧ (∃T. T ∈ ℬ ∧ U ⊆ T)"
and fin: "⋀x. x ∈ U - S ⟹ ∃V. open V ∧ x ∈ V ∧ finite {U. U ∈ 𝒞 ∧ U ∩ V ≠ {}}"
by (rule paracompact [OF USS]) auto
have "∃v a. v ∈ U ∧ v ∉ S ∧ a ∈ S ∧
T ⊆ ball v (setdist {v} S / 2) ∧
dist v a ≤ 2 * setdist {v} S" if "T ∈ 𝒞" for T
proof -
obtain v where v: "T ⊆ ball v (setdist {v} S / 2)" "v ∈ U" "v ∉ S"
using ‹T ∈ 𝒞› nbrhd by (force simp: ℬ_def)
then obtain a where "a ∈ S" "dist v a < 2 * setdist {v} S"
using setdist_ltE [of "{v}" S "2 * setdist {v} S"]
using False sd_pos by force
with v show ?thesis
by force
qed
then obtain 𝒱 𝒜 where
VA: "⋀T. T ∈ 𝒞 ⟹ 𝒱 T ∈ U ∧ 𝒱 T ∉ S ∧ 𝒜 T ∈ S ∧
T ⊆ ball (𝒱 T) (setdist {𝒱 T} S / 2) ∧
dist (𝒱 T) (𝒜 T) ≤ 2 * setdist {𝒱 T} S"
by metis
have sdle: "setdist {𝒱 T} S ≤ 2 * setdist {v} S" if "T ∈ 𝒞" "v ∈ T" for T v
using setdist_Lipschitz [of "𝒱 T" S v] VA [OF ‹T ∈ 𝒞›] ‹v ∈ T› by auto
have d6: "dist a (𝒜 T) ≤ 6 * dist a v" if "T ∈ 𝒞" "v ∈ T" "a ∈ S" for T v a
proof -
have "dist (𝒱 T) v < setdist {𝒱 T} S / 2"
using that VA mem_ball by blast
also have "… ≤ setdist {v} S"
using sdle [OF ‹T ∈ 𝒞› ‹v ∈ T›] by simp
also have vS: "setdist {v} S ≤ dist a v"
by (simp add: setdist_le_dist setdist_sym ‹a ∈ S›)
finally have VTV: "dist (𝒱 T) v < dist a v" .
have VTS: "setdist {𝒱 T} S ≤ 2 * dist a v"
using sdle that vS by force
have "dist a (𝒜 T) ≤ dist a v + dist v (𝒱 T) + dist (𝒱 T) (𝒜 T)"
by (metis add.commute add_le_cancel_left dist_commute dist_triangle2 dist_triangle_le)
also have "… ≤ dist a v + dist a v + dist (𝒱 T) (𝒜 T)"
using VTV by (simp add: dist_commute)
also have "… ≤ 2 * dist a v + 2 * setdist {𝒱 T} S"
using VA [OF ‹T ∈ 𝒞›] by auto
finally show ?thesis
using VTS by linarith
qed
obtain H :: "['a set, 'a] ⇒ real"
where Hcont: "⋀Z. Z ∈ 𝒞 ⟹ continuous_on (U-S) (H Z)"
and Hge0: "⋀Z x. ⟦Z ∈ 𝒞; x ∈ U-S⟧ ⟹ 0 ≤ H Z x"
and Heq0: "⋀x Z. ⟦Z ∈ 𝒞; x ∈ U-S; x ∉ Z⟧ ⟹ H Z x = 0"
and H1: "⋀x. x ∈ U-S ⟹ supp_sum (λW. H W x) 𝒞 = 1"
and Hfin: "⋀x. x ∈ U-S ⟹ ∃V. open V ∧ x ∈ V ∧ finite {U ∈ 𝒞. ∃x∈V. H U x ≠ 0}"
apply (rule subordinate_partition_of_unity [OF USsub _ fin])
using nbrhd by auto
define g where "g ≡ λx. if x ∈ S then f x else supp_sum (λT. H T x *⇩R f(𝒜 T)) 𝒞"
show ?thesis
proof (rule that)
show "continuous_on U g"
proof (clarsimp simp: continuous_on_eq_continuous_within)
fix a assume "a ∈ U"
show "continuous (at a within U) g"
proof (cases "a ∈ S")
case True show ?thesis
proof (clarsimp simp add: continuous_within_topological)
fix W
assume "open W" "g a ∈ W"
then obtain e where "0 < e" and e: "ball (f a) e ⊆ W"
using openE True g_def by auto
have "continuous (at a within S) f"
using True contf continuous_on_eq_continuous_within by blast
then obtain d where "0 < d"
and d: "⋀x. ⟦x ∈ S; dist x a < d⟧ ⟹ dist (f x) (f a) < e"
using continuous_within_eps_delta ‹0 < e› by force
have "g y ∈ ball (f a) e" if "y ∈ U" and y: "y ∈ ball a (d / 6)" for y
proof (cases "y ∈ S")
case True
then have "dist (f a) (f y) < e"
by (metis ball_divide_subset_numeral dist_commute in_mono mem_ball y d)
then show ?thesis
by (simp add: True g_def)
next
case False
have *: "dist (f (𝒜 T)) (f a) < e" if "T ∈ 𝒞" "H T y ≠ 0" for T
proof -
have "y ∈ T"
using Heq0 that False ‹y ∈ U› by blast
have "dist (𝒜 T) a < d"
using d6 [OF ‹T ∈ 𝒞› ‹y ∈ T› ‹a ∈ S›] y
by (simp add: dist_commute mult.commute)
then show ?thesis
using VA [OF ‹T ∈ 𝒞›] by (auto simp: d)
qed
have "supp_sum (λT. H T y *⇩R f (𝒜 T)) 𝒞 ∈ ball (f a) e"
apply (rule convex_supp_sum [OF convex_ball])
apply (simp_all add: False H1 Hge0 ‹y ∈ U›)
by (metis dist_commute *)
then show ?thesis
by (simp add: False g_def)
qed
then show "∃A. open A ∧ a ∈ A ∧ (∀y∈U. y ∈ A ⟶ g y ∈ W)"
apply (rule_tac x = "ball a (d / 6)" in exI)
using e ‹0 < d› by fastforce
qed
next
case False
obtain N where N: "open N" "a ∈ N"
and finN: "finite {U ∈ 𝒞. ∃a∈N. H U a ≠ 0}"
using Hfin False ‹a ∈ U› by auto
have oUS: "openin (top_of_set U) (U - S)"
using cloin by (simp add: openin_diff)
have HcontU: "continuous (at a within U) (H T)" if "T ∈ 𝒞" for T
using Hcont [OF ‹T ∈ 𝒞›] False ‹a ∈ U› ‹T ∈ 𝒞›
apply (simp add: continuous_on_eq_continuous_within continuous_within)
apply (rule Lim_transform_within_set)
using oUS
apply (force simp: eventually_at openin_contains_ball dist_commute dest!: bspec)+
done
show ?thesis
proof (rule continuous_transform_within_openin [OF _ oUS])
show "continuous (at a within U) (λx. supp_sum (λT. H T x *⇩R f (𝒜 T)) 𝒞)"
proof (rule continuous_transform_within_openin)
show "continuous (at a within U)
(λx. ∑T∈{U ∈ 𝒞. ∃x∈N. H U x ≠ 0}. H T x *⇩R f (𝒜 T))"
by (force intro: continuous_intros HcontU)+
next
show "openin (top_of_set U) ((U - S) ∩ N)"
using N oUS openin_trans by blast
next
show "a ∈ (U - S) ∩ N" using False ‹a ∈ U› N by blast
next
show "⋀x. x ∈ (U - S) ∩ N ⟹
(∑T ∈ {U ∈ 𝒞. ∃x∈N. H U x ≠ 0}. H T x *⇩R f (𝒜 T))
= supp_sum (λT. H T x *⇩R f (𝒜 T)) 𝒞"
by (auto simp: supp_sum_def support_on_def
intro: sum.mono_neutral_right [OF finN])
qed
next
show "a ∈ U - S" using False ‹a ∈ U› by blast
next
show "⋀x. x ∈ U - S ⟹ supp_sum (λT. H T x *⇩R f (𝒜 T)) 𝒞 = g x"
by (simp add: g_def)
qed
qed
qed
show "g ` U ⊆ C"
using ‹f ` S ⊆ C› VA
by (fastforce simp: g_def Hge0 intro!: convex_supp_sum [OF ‹convex C›] H1)
show "⋀x. x ∈ S ⟹ g x = f x"
by (simp add: g_def)
qed
qed
corollary Tietze:
fixes f :: "'a::{metric_space,second_countable_topology} ⇒ 'b::real_inner"
assumes "continuous_on S f"
and "closedin (top_of_set U) S"
and "0 ≤ B"
and "⋀x. x ∈ S ⟹ norm(f x) ≤ B"
obtains g where "continuous_on U g" "⋀x. x ∈ S ⟹ g x = f x"
"⋀x. x ∈ U ⟹ norm(g x) ≤ B"
using assms by (auto simp: image_subset_iff intro: Dugundji [of "cball 0 B" U S f])
corollary Tietze_closed_interval:
fixes f :: "'a::{metric_space,second_countable_topology} ⇒ 'b::euclidean_space"
assumes "continuous_on S f"
and "closedin (top_of_set U) S"
and "cbox a b ≠ {}"
and "⋀x. x ∈ S ⟹ f x ∈ cbox a b"
obtains g where "continuous_on U g" "⋀x. x ∈ S ⟹ g x = f x"
"⋀x. x ∈ U ⟹ g x ∈ cbox a b"
apply (rule Dugundji [of "cbox a b" U S f])
using assms by auto
corollary Tietze_closed_interval_1:
fixes f :: "'a::{metric_space,second_countable_topology} ⇒ real"
assumes "continuous_on S f"
and "closedin (top_of_set U) S"
and "a ≤ b"
and "⋀x. x ∈ S ⟹ f x ∈ cbox a b"
obtains g where "continuous_on U g" "⋀x. x ∈ S ⟹ g x = f x"
"⋀x. x ∈ U ⟹ g x ∈ cbox a b"
apply (rule Dugundji [of "cbox a b" U S f])
using assms by (auto simp: image_subset_iff)
corollary Tietze_open_interval:
fixes f :: "'a::{metric_space,second_countable_topology} ⇒ 'b::euclidean_space"
assumes "continuous_on S f"
and "closedin (top_of_set U) S"
and "box a b ≠ {}"
and "⋀x. x ∈ S ⟹ f x ∈ box a b"
obtains g where "continuous_on U g" "⋀x. x ∈ S ⟹ g x = f x"
"⋀x. x ∈ U ⟹ g x ∈ box a b"
apply (rule Dugundji [of "box a b" U S f])
using assms by auto
corollary Tietze_open_interval_1:
fixes f :: "'a::{metric_space,second_countable_topology} ⇒ real"
assumes "continuous_on S f"
and "closedin (top_of_set U) S"
and "a < b"
and no: "⋀x. x ∈ S ⟹ f x ∈ box a b"
obtains g where "continuous_on U g" "⋀x. x ∈ S ⟹ g x = f x"
"⋀x. x ∈ U ⟹ g x ∈ box a b"
apply (rule Dugundji [of "box a b" U S f])
using assms by (auto simp: image_subset_iff)
corollary Tietze_unbounded:
fixes f :: "'a::{metric_space,second_countable_topology} ⇒ 'b::real_inner"
assumes "continuous_on S f"
and "closedin (top_of_set U) S"
obtains g where "continuous_on U g" "⋀x. x ∈ S ⟹ g x = f x"
apply (rule Dugundji [of UNIV U S f])
using assms by auto
end