First tranche of the Homology development: Simplices
[dummy commit to run testboard again]
(* Author: LCP, ported from HOL Light
*)
section\<open>Euclidean space and n-spheres, as subtopologies of n-dimensional space\<close>
theory Abstract_Euclidean_Space
imports Homotopy Locally T1_Spaces
begin
subsection \<open>Euclidean spaces as abstract topologies\<close>
definition Euclidean_space :: "nat \<Rightarrow> (nat \<Rightarrow> real) topology"
where "Euclidean_space n \<equiv> subtopology (powertop_real UNIV) {x. \<forall>i\<ge>n. x i = 0}"
lemma topspace_Euclidean_space:
"topspace(Euclidean_space n) = {x. \<forall>i\<ge>n. x i = 0}"
by (simp add: Euclidean_space_def)
lemma nonempty_Euclidean_space: "topspace(Euclidean_space n) \<noteq> {}"
by (force simp: topspace_Euclidean_space)
lemma subset_Euclidean_space [simp]:
"topspace(Euclidean_space m) \<subseteq> topspace(Euclidean_space n) \<longleftrightarrow> m \<le> n"
apply (simp add: topspace_Euclidean_space subset_iff, safe)
apply (drule_tac x="(\<lambda>i. if i < m then 1 else 0)" in spec)
apply auto
using not_less by fastforce
lemma topspace_Euclidean_space_alt:
"topspace(Euclidean_space n) = (\<Inter>i \<in> {n..}. {x. x \<in> topspace(powertop_real UNIV) \<and> x i \<in> {0}})"
by (auto simp: topspace_Euclidean_space)
lemma closedin_Euclidean_space:
"closedin (powertop_real UNIV) (topspace(Euclidean_space n))"
proof -
have "closedin (powertop_real UNIV) {x. x i = 0}" if "n \<le> i" for i
proof -
have "closedin (powertop_real UNIV) {x \<in> topspace (powertop_real UNIV). x i \<in> {0}}"
proof (rule closedin_continuous_map_preimage)
show "continuous_map (powertop_real UNIV) euclideanreal (\<lambda>x. x i)"
by (metis UNIV_I continuous_map_product_coordinates)
show "closedin euclideanreal {0}"
by simp
qed
then show ?thesis
by auto
qed
then show ?thesis
unfolding topspace_Euclidean_space_alt
by force
qed
lemma closedin_Euclidean_imp_closed: "closedin (Euclidean_space m) S \<Longrightarrow> closed S"
by (metis Euclidean_space_def closed_closedin closedin_Euclidean_space closedin_closed_subtopology euclidean_product_topology topspace_Euclidean_space)
lemma closedin_Euclidean_space_iff:
"closedin (Euclidean_space m) S \<longleftrightarrow> closed S \<and> S \<subseteq> topspace (Euclidean_space m)"
(is "?lhs \<longleftrightarrow> ?rhs")
proof
show "?lhs \<Longrightarrow> ?rhs"
using closedin_closed_subtopology topspace_Euclidean_space
by (fastforce simp: topspace_Euclidean_space_alt closedin_Euclidean_imp_closed)
show "?rhs \<Longrightarrow> ?lhs"
apply (simp add: closedin_subtopology Euclidean_space_def)
by (metis (no_types) closed_closedin euclidean_product_topology inf.orderE)
qed
lemma continuous_map_componentwise_Euclidean_space:
"continuous_map X (Euclidean_space n) (\<lambda>x i. if i < n then f x i else 0) \<longleftrightarrow>
(\<forall>i < n. continuous_map X euclideanreal (\<lambda>x. f x i))"
proof -
have *: "continuous_map X euclideanreal (\<lambda>x. if k < n then f x k else 0)"
if "\<And>i. i<n \<Longrightarrow> continuous_map X euclideanreal (\<lambda>x. f x i)" for k
by (intro continuous_intros that)
show ?thesis
unfolding Euclidean_space_def continuous_map_in_subtopology
by (fastforce simp: continuous_map_componentwise_UNIV * elim: continuous_map_eq)
qed
lemma continuous_map_Euclidean_space_add [continuous_intros]:
"\<lbrakk>continuous_map X (Euclidean_space n) f; continuous_map X (Euclidean_space n) g\<rbrakk>
\<Longrightarrow> continuous_map X (Euclidean_space n) (\<lambda>x i. f x i + g x i)"
unfolding Euclidean_space_def continuous_map_in_subtopology
by (fastforce simp add: continuous_map_componentwise_UNIV continuous_map_add)
lemma continuous_map_Euclidean_space_diff [continuous_intros]:
"\<lbrakk>continuous_map X (Euclidean_space n) f; continuous_map X (Euclidean_space n) g\<rbrakk>
\<Longrightarrow> continuous_map X (Euclidean_space n) (\<lambda>x i. f x i - g x i)"
unfolding Euclidean_space_def continuous_map_in_subtopology
by (fastforce simp add: continuous_map_componentwise_UNIV continuous_map_diff)
lemma continuous_map_Euclidean_space_iff:
"continuous_map (Euclidean_space m) euclideanreal g
= continuous_on (topspace (Euclidean_space m)) g"
proof
assume "continuous_map (Euclidean_space m) euclideanreal g"
then have "continuous_map (top_of_set {f. \<forall>n\<ge>m. f n = 0}) euclideanreal g"
by (simp add: Euclidean_space_def euclidean_product_topology)
then show "continuous_on (topspace (Euclidean_space m)) g"
by (metis continuous_map_subtopology_eu subtopology_topspace topspace_Euclidean_space)
next
assume "continuous_on (topspace (Euclidean_space m)) g"
then have "continuous_map (top_of_set {f. \<forall>n\<ge>m. f n = 0}) euclideanreal g"
by (metis (lifting) continuous_map_into_fulltopology continuous_map_subtopology_eu order_refl topspace_Euclidean_space)
then show "continuous_map (Euclidean_space m) euclideanreal g"
by (simp add: Euclidean_space_def euclidean_product_topology)
qed
lemma cm_Euclidean_space_iff_continuous_on:
"continuous_map (subtopology (Euclidean_space m) S) (Euclidean_space n) f
\<longleftrightarrow> continuous_on (topspace (subtopology (Euclidean_space m) S)) f \<and>
f ` (topspace (subtopology (Euclidean_space m) S)) \<subseteq> topspace (Euclidean_space n)"
(is "?P \<longleftrightarrow> ?Q \<and> ?R")
proof -
have ?Q if ?P
proof -
have "\<And>n. Euclidean_space n = top_of_set {f. \<forall>m\<ge>n. f m = 0}"
by (simp add: Euclidean_space_def euclidean_product_topology)
with that show ?thesis
by (simp add: subtopology_subtopology)
qed
moreover
have ?R if ?P
using that by (simp add: image_subset_iff continuous_map_def)
moreover
have ?P if ?Q ?R
proof -
have "continuous_map (top_of_set (topspace (subtopology (subtopology (powertop_real UNIV) {f. \<forall>n\<ge>m. f n = 0}) S))) (top_of_set (topspace (subtopology (powertop_real UNIV) {f. \<forall>na\<ge>n. f na = 0}))) f"
using Euclidean_space_def that by auto
then show ?thesis
by (simp add: Euclidean_space_def euclidean_product_topology subtopology_subtopology)
qed
ultimately show ?thesis
by auto
qed
lemma homeomorphic_Euclidean_space_product_topology:
"Euclidean_space n homeomorphic_space product_topology (\<lambda>i. euclideanreal) {..<n}"
proof -
have cm: "continuous_map (product_topology (\<lambda>i. euclideanreal) {..<n})
euclideanreal (\<lambda>x. if k < n then x k else 0)" for k
by (auto intro: continuous_map_if continuous_map_product_projection)
show ?thesis
unfolding homeomorphic_space_def homeomorphic_maps_def
apply (rule_tac x="\<lambda>f. restrict f {..<n}" in exI)
apply (rule_tac x="\<lambda>f i. if i < n then f i else 0" in exI)
apply (simp add: Euclidean_space_def topspace_subtopology continuous_map_in_subtopology)
apply (intro conjI continuous_map_from_subtopology)
apply (force simp: continuous_map_componentwise cm intro: continuous_map_product_projection)+
done
qed
lemma contractible_Euclidean_space [simp]: "contractible_space (Euclidean_space n)"
using homeomorphic_Euclidean_space_product_topology contractible_space_euclideanreal
contractible_space_product_topology homeomorphic_space_contractibility by blast
lemma path_connected_Euclidean_space: "path_connected_space (Euclidean_space n)"
by (simp add: contractible_imp_path_connected_space)
lemma connected_Euclidean_space: "connected_space (Euclidean_space n)"
by (simp add: contractible_Euclidean_space contractible_imp_connected_space)
lemma locally_path_connected_Euclidean_space:
"locally_path_connected_space (Euclidean_space n)"
apply (simp add: homeomorphic_locally_path_connected_space [OF homeomorphic_Euclidean_space_product_topology [of n]]
locally_path_connected_space_product_topology)
using locally_path_connected_space_euclideanreal by auto
lemma compact_Euclidean_space:
"compact_space (Euclidean_space n) \<longleftrightarrow> n = 0"
by (auto simp: homeomorphic_compact_space [OF homeomorphic_Euclidean_space_product_topology] compact_space_product_topology)
subsection\<open>n-dimensional spheres\<close>
definition nsphere where
"nsphere n \<equiv> subtopology (Euclidean_space (Suc n)) { x. (\<Sum>i\<le>n. x i ^ 2) = 1 }"
lemma nsphere:
"nsphere n = subtopology (powertop_real UNIV)
{x. (\<Sum>i\<le>n. x i ^ 2) = 1 \<and> (\<forall>i>n. x i = 0)}"
by (simp add: nsphere_def Euclidean_space_def subtopology_subtopology Suc_le_eq Collect_conj_eq Int_commute)
lemma continuous_map_nsphere_projection: "continuous_map (nsphere n) euclideanreal (\<lambda>x. x k)"
unfolding nsphere
by (blast intro: continuous_map_from_subtopology [OF continuous_map_product_projection])
lemma in_topspace_nsphere: "(\<lambda>n. if n = 0 then 1 else 0) \<in> topspace (nsphere n)"
by (simp add: nsphere_def topspace_Euclidean_space power2_eq_square if_distrib [where f = "\<lambda>x. x * _"] cong: if_cong)
lemma nonempty_nsphere [simp]: "~ (topspace(nsphere n) = {})"
using in_topspace_nsphere by auto
lemma subtopology_nsphere_equator:
"subtopology (nsphere (Suc n)) {x. x(Suc n) = 0} = nsphere n"
proof -
have "({x. (\<Sum>i\<le>n. (x i)\<^sup>2) + (x (Suc n))\<^sup>2 = 1 \<and> (\<forall>i>Suc n. x i = 0)} \<inter> {x. x (Suc n) = 0})
= {x. (\<Sum>i\<le>n. (x i)\<^sup>2) = 1 \<and> (\<forall>i>n. x i = (0::real))}"
using Suc_lessI [of n] by (fastforce simp: set_eq_iff)
then show ?thesis
by (simp add: nsphere subtopology_subtopology)
qed
lemma continuous_map_nsphere_reflection:
"continuous_map (nsphere n) (nsphere n) (\<lambda>x i. if i = k then -x i else x i)"
proof -
have cm: "continuous_map (powertop_real UNIV) euclideanreal (\<lambda>x. if j = k then - x j else x j)" for j
proof (cases "j=k")
case True
then show ?thesis
by simp (metis UNIV_I continuous_map_product_projection)
next
case False
then show ?thesis
by (auto intro: continuous_map_product_projection)
qed
have eq: "(if i = k then x k * x k else x i * x i) = x i * x i" for i and x :: "nat \<Rightarrow> real"
by simp
show ?thesis
apply (simp add: nsphere continuous_map_in_subtopology continuous_map_componentwise_UNIV
continuous_map_from_subtopology cm)
apply (intro conjI allI impI continuous_intros continuous_map_from_subtopology continuous_map_product_projection)
apply (auto simp: power2_eq_square if_distrib [where f = "\<lambda>x. x * _"] eq cong: if_cong)
done
qed
proposition contractible_space_upper_hemisphere:
assumes "k \<le> n"
shows "contractible_space(subtopology (nsphere n) {x. x k \<ge> 0})"
proof -
define p:: "nat \<Rightarrow> real" where "p \<equiv> \<lambda>i. if i = k then 1 else 0"
have "p \<in> topspace(nsphere n)"
using assms
by (simp add: nsphere topspace_subtopology p_def power2_eq_square if_distrib [where f = "\<lambda>x. x * _"] cong: if_cong)
let ?g = "\<lambda>x i. x i / sqrt(\<Sum>j\<le>n. x j ^ 2)"
let ?h = "\<lambda>(t,q) i. (1 - t) * q i + t * p i"
let ?Y = "subtopology (Euclidean_space (Suc n)) {x. 0 \<le> x k \<and> (\<exists>i\<le>n. x i \<noteq> 0)}"
have "continuous_map (prod_topology (top_of_set {0..1}) (subtopology (nsphere n) {x. 0 \<le> x k}))
(subtopology (nsphere n) {x. 0 \<le> x k}) (?g \<circ> ?h)"
proof (rule continuous_map_compose)
have *: "\<lbrakk>0 \<le> b k; (\<Sum>i\<le>n. (b i)\<^sup>2) = 1; \<forall>i>n. b i = 0; 0 \<le> a; a \<le> 1\<rbrakk>
\<Longrightarrow> \<exists>i. (i = k \<longrightarrow> (1 - a) * b k + a \<noteq> 0) \<and>
(i \<noteq> k \<longrightarrow> i \<le> n \<and> a \<noteq> 1 \<and> b i \<noteq> 0)" for a::real and b
apply (cases "a \<noteq> 1 \<and> b k = 0"; simp)
apply (metis (no_types, lifting) atMost_iff sum.neutral zero_power2)
by (metis add.commute add_le_same_cancel2 diff_ge_0_iff_ge diff_zero less_eq_real_def mult_eq_0_iff mult_nonneg_nonneg not_le numeral_One zero_neq_numeral)
show "continuous_map (prod_topology (top_of_set {0..1}) (subtopology (nsphere n) {x. 0 \<le> x k})) ?Y ?h"
using assms
apply (auto simp: * nsphere topspace_subtopology continuous_map_componentwise_UNIV
prod_topology_subtopology subtopology_subtopology case_prod_unfold
continuous_map_in_subtopology Euclidean_space_def p_def if_distrib [where f = "\<lambda>x. _ * x"] cong: if_cong)
apply (intro continuous_map_prod_snd continuous_intros continuous_map_from_subtopology)
apply auto
done
next
have 1: "\<And>x i. \<lbrakk> i \<le> n; x i \<noteq> 0\<rbrakk> \<Longrightarrow> (\<Sum>i\<le>n. (x i / sqrt (\<Sum>j\<le>n. (x j)\<^sup>2))\<^sup>2) = 1"
by (force simp: sum_nonneg sum_nonneg_eq_0_iff divide_simps simp flip: sum_divide_distrib)
have cm: "continuous_map ?Y (nsphere n) (\<lambda>x i. x i / sqrt (\<Sum>j\<le>n. (x j)\<^sup>2))"
unfolding Euclidean_space_def nsphere subtopology_subtopology continuous_map_in_subtopology
proof (intro continuous_intros conjI)
show "continuous_map
(subtopology (powertop_real UNIV) ({x. \<forall>i\<ge>Suc n. x i = 0} \<inter> {x. 0 \<le> x k \<and> (\<exists>i\<le>n. x i \<noteq> 0)}))
(powertop_real UNIV) (\<lambda>x i. x i / sqrt (\<Sum>j\<le>n. (x j)\<^sup>2))"
unfolding continuous_map_componentwise
by (intro continuous_intros conjI ballI) (auto simp: sum_nonneg_eq_0_iff)
qed (auto simp: 1)
show "continuous_map ?Y (subtopology (nsphere n) {x. 0 \<le> x k}) (\<lambda>x i. x i / sqrt (\<Sum>j\<le>n. (x j)\<^sup>2))"
by (force simp: cm sum_nonneg continuous_map_in_subtopology if_distrib [where f = "\<lambda>x. _ * x"] cong: if_cong)
qed
moreover have "(?g \<circ> ?h) (0, x) = x"
if "x \<in> topspace (subtopology (nsphere n) {x. 0 \<le> x k})" for x
using that
by (simp add: assms topspace_subtopology nsphere)
moreover
have "(?g \<circ> ?h) (1, x) = p"
if "x \<in> topspace (subtopology (nsphere n) {x. 0 \<le> x k})" for x
by (force simp: assms p_def power2_eq_square if_distrib [where f = "\<lambda>x. x * _"] cong: if_cong)
ultimately
show ?thesis
apply (simp add: contractible_space_def homotopic_with)
apply (rule_tac x=p in exI)
apply (rule_tac x="?g \<circ> ?h" in exI, force)
done
qed
corollary contractible_space_lower_hemisphere:
assumes "k \<le> n"
shows "contractible_space(subtopology (nsphere n) {x. x k \<le> 0})"
proof -
have "contractible_space (subtopology (nsphere n) {x. 0 \<le> x k}) = ?thesis"
proof (rule homeomorphic_space_contractibility)
show "subtopology (nsphere n) {x. 0 \<le> x k} homeomorphic_space subtopology (nsphere n) {x. x k \<le> 0}"
unfolding homeomorphic_space_def homeomorphic_maps_def
apply (rule_tac x="\<lambda>x i. if i = k then -(x i) else x i" in exI)+
apply (auto simp: continuous_map_in_subtopology continuous_map_from_subtopology
continuous_map_nsphere_reflection)
done
qed
then show ?thesis
using contractible_space_upper_hemisphere [OF assms] by metis
qed
proposition nullhomotopic_nonsurjective_sphere_map:
assumes f: "continuous_map (nsphere p) (nsphere p) f"
and fim: "f ` (topspace(nsphere p)) \<noteq> topspace(nsphere p)"
obtains a where "homotopic_with (\<lambda>x. True) (nsphere p) (nsphere p) f (\<lambda>x. a)"
proof -
obtain a where a: "a \<in> topspace(nsphere p)" "a \<notin> f ` (topspace(nsphere p))"
using fim continuous_map_image_subset_topspace f by blast
then have a1: "(\<Sum>i\<le>p. (a i)\<^sup>2) = 1" and a0: "\<And>i. i > p \<Longrightarrow> a i = 0"
by (simp_all add: nsphere)
have f1: "(\<Sum>j\<le>p. (f x j)\<^sup>2) = 1" if "x \<in> topspace (nsphere p)" for x
proof -
have "f x \<in> topspace (nsphere p)"
using continuous_map_image_subset_topspace f that by blast
then show ?thesis
by (simp add: nsphere)
qed
show thesis
proof
let ?g = "\<lambda>x i. x i / sqrt(\<Sum>j\<le>p. x j ^ 2)"
let ?h = "\<lambda>(t,x) i. (1 - t) * f x i - t * a i"
let ?Y = "subtopology (Euclidean_space(Suc p)) (- {\<lambda>i. 0})"
let ?T01 = "top_of_set {0..1::real}"
have 1: "continuous_map (prod_topology ?T01 (nsphere p)) (nsphere p) (?g \<circ> ?h)"
proof (rule continuous_map_compose)
have "continuous_map (prod_topology ?T01 (nsphere p)) euclideanreal ((\<lambda>x. f x k) \<circ> snd)" for k
unfolding nsphere
apply (simp add: continuous_map_of_snd)
apply (rule continuous_map_compose [of _ "nsphere p" f, unfolded o_def])
using f apply (simp add: nsphere)
by (simp add: continuous_map_nsphere_projection)
then have "continuous_map (prod_topology ?T01 (nsphere p)) euclideanreal (\<lambda>r. ?h r k)"
for k
unfolding case_prod_unfold o_def
by (intro continuous_map_into_fulltopology [OF continuous_map_fst] continuous_intros) auto
moreover have "?h ` ({0..1} \<times> topspace (nsphere p)) \<subseteq> {x. \<forall>i\<ge>Suc p. x i = 0}"
using continuous_map_image_subset_topspace [OF f]
by (auto simp: nsphere image_subset_iff a0)
moreover have "(\<lambda>i. 0) \<notin> ?h ` ({0..1} \<times> topspace (nsphere p))"
proof clarify
fix t b
assume eq: "(\<lambda>i. 0) = (\<lambda>i. (1 - t) * f b i - t * a i)" and "t \<in> {0..1}" and b: "b \<in> topspace (nsphere p)"
have "(1 - t)\<^sup>2 = (\<Sum>i\<le>p. ((1 - t) * f b i)^2)"
using f1 [OF b] by (simp add: power_mult_distrib flip: sum_distrib_left)
also have "\<dots> = (\<Sum>i\<le>p. (t * a i)^2)"
using eq by (simp add: fun_eq_iff)
also have "\<dots> = t\<^sup>2"
using a1 by (simp add: power_mult_distrib flip: sum_distrib_left)
finally have "1 - t = t"
by (simp add: power2_eq_iff)
then have *: "t = 1/2"
by simp
have fba: "f b \<noteq> a"
using a(2) b by blast
then show False
using eq unfolding * by (simp add: fun_eq_iff)
qed
ultimately show "continuous_map (prod_topology ?T01 (nsphere p)) ?Y ?h"
by (simp add: Euclidean_space_def continuous_map_in_subtopology continuous_map_componentwise_UNIV)
next
have *: "\<lbrakk>\<forall>i\<ge>Suc p. x i = 0; x \<noteq> (\<lambda>i. 0)\<rbrakk> \<Longrightarrow> (\<Sum>j\<le>p. (x j)\<^sup>2) \<noteq> 0" for x :: "nat \<Rightarrow> real"
by (force simp: fun_eq_iff not_less_eq_eq sum_nonneg_eq_0_iff)
show "continuous_map ?Y (nsphere p) ?g"
apply (simp add: Euclidean_space_def continuous_map_in_subtopology continuous_map_componentwise_UNIV
nsphere continuous_map_componentwise subtopology_subtopology)
apply (intro conjI allI continuous_intros continuous_map_from_subtopology [OF continuous_map_product_projection])
apply (simp_all add: *)
apply (force simp: sum_nonneg fun_eq_iff not_less_eq_eq sum_nonneg_eq_0_iff power_divide simp flip: sum_divide_distrib)
done
qed
have 2: "(?g \<circ> ?h) (0, x) = f x" if "x \<in> topspace (nsphere p)" for x
using that f1 by simp
have 3: "(?g \<circ> ?h) (1, x) = (\<lambda>i. - a i)" for x
using a by (force simp: divide_simps nsphere)
then show "homotopic_with (\<lambda>x. True) (nsphere p) (nsphere p) f (\<lambda>x. (\<lambda>i. - a i))"
by (force simp: homotopic_with intro: 1 2 3)
qed
qed
lemma Hausdorff_Euclidean_space:
"Hausdorff_space (Euclidean_space n)"
unfolding Euclidean_space_def
by (rule Hausdorff_space_subtopology) (metis Hausdorff_space_euclidean euclidean_product_topology)
end