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completely regular spaces and locally compact implies uniform #1331

Merged
merged 14 commits into from
Oct 27, 2024
25 changes: 25 additions & 0 deletions CHANGELOG_UNRELEASED.md
Original file line number Diff line number Diff line change
Expand Up @@ -4,8 +4,33 @@

### Added

- in file `separation_axioms.v`,
+ new lemmas `compact_normal_local`, and `compact_normal`.

- in file `topology_theory/one_point_compactification.v`,
+ new definitions `one_point_compactification`, and `one_point_nbhs`.
+ new lemmas `one_point_compactification_compact`,
`one_point_compactification_some_nbhs`,
`one_point_compactification_some_continuous`,
`one_point_compactification_open_some`,
`one_point_compactification_weak_topology`, and
`one_point_compactification_hausdorff`.

- in file `normedtype.v`,
+ new definition `type` (in module `completely_regular_uniformity`)
+ new lemmas `normal_completely_regular`,
`one_point_compactification_completely_reg`,
`nbhs_one_point_compactification_weakE`,
`locally_compact_completely_regular`, and
`completely_regular_regular`.

### Changed

- in file `normedtype.v`,
changed `completely_regular_space` to depend on uniform separators
which removes the dependency on `R`. The old formulation can be
recovered easily with `uniform_separatorP`.

### Renamed

### Generalized
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1 change: 1 addition & 0 deletions _CoqProject
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Expand Up @@ -42,6 +42,7 @@ theories/topology_theory/uniform_structure.v
theories/topology_theory/weak_topology.v
theories/topology_theory/num_topology.v
theories/topology_theory/quotient_topology.v
theories/topology_theory/one_point_compactification.v

theories/separation_axioms.v
theories/function_spaces.v
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2 changes: 1 addition & 1 deletion classical/filter.v
Original file line number Diff line number Diff line change
Expand Up @@ -1565,7 +1565,7 @@ move=> A [n _]; elim: n A.
by move=> n IH A /= [B snB [C snC <-]]; apply: finI_fromI; apply: IH.
Qed.

Lemma smallest_filter_finI {T : choiceType} (D : set T) f :
Lemma smallest_filter_finI {I T : choiceType} (D : set I) (f : I -> set T) :
filter_from (finI_from D f) id = smallest (@Filter T) (f @` D).
Proof. by rewrite filterI_iter_finI filterI_iterE. Qed.

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1 change: 1 addition & 0 deletions theories/Make
Original file line number Diff line number Diff line change
Expand Up @@ -28,6 +28,7 @@ topology_theory/uniform_structure.v
topology_theory/weak_topology.v
topology_theory/num_topology.v
topology_theory/quotient_topology.v
topology_theory/one_point_compactification.v

ereal.v
separation_axioms.v
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147 changes: 130 additions & 17 deletions theories/normedtype.v
Original file line number Diff line number Diff line change
Expand Up @@ -50,6 +50,11 @@ From mathcomp Require Export separation_axioms.
(* `uniform_separator A B` *)
(* completely_regular_space == a space where points and closed sets can *)
(* be separated by a function into R *)
(* completely_regular_uniformity == equips a completely_regular_space with *)
(* the uniformity induced by continuous *)
(* functions into the reals *)
(* note this uniformity is always the only *)
(* choice, so its placed in a module *)
(* uniform_separator A B == there is a suitable uniform space and *)
(* entourage separating A and B *)
(* nbhs_norm == neighborhoods defined by the norm *)
Expand Down Expand Up @@ -3687,17 +3692,19 @@ Proof. exact: (normal_spaceP 0%N 1%N). Qed.
End normalP.

Section completely_regular.

Context {R : realType}.

Definition completely_regular_space {T : topologicalType} :=
forall (a : T) (B : set T), closed B -> ~ B a -> exists f : T -> R, [/\
continuous f,
f a = 0 &
f @` B `<=` [set 1] ].
(**md This is equivalent to uniformizable. Note there is a subtle
distinction between being uniformizable and being uniformType.
There is often more than one possible uniformity, and being a
uniformType has a specific one.

If you don't care, you can use the `completely_regular_uniformity.type`
which builds the uniformity.
*)
Definition completely_regular_space (T : topologicalType) :=
forall (a : T) (B : set T), closed B -> ~ B a -> uniform_separator [set a] B.

(* Ideally, R should be an instance of realType here,
rather than a section variable. *)
Lemma point_uniform_separator {T : uniformType} (x : T) (B : set T) :
closed B -> ~ B x -> uniform_separator [set x] B.
Proof.
Expand All @@ -3711,36 +3718,142 @@ Qed.

Lemma uniform_completely_regular {T : uniformType} :
@completely_regular_space T.
Proof. by move=> x B clB Bx; exact: point_uniform_separator. Qed.

Lemma normal_completely_regular {T : topologicalType} :
normal_space T -> accessible_space T -> completely_regular_space T.
Proof.
move=> x B clB Bx.
have /(@uniform_separatorP _ R) [f] := point_uniform_separator clB Bx.
by case=> ? _; rewrite image_set1 => fx ?; exists f; split => //; exact: fx.
move/normal_separatorP => + /accessible_closed_set1 cl1 x A ? ?; apply => //.
by apply/disjoints_subset => ? ->.
Qed.

End completely_regular.

Section pseudometric_normal.

Lemma uniform_regular {X : uniformType} : @regular_space X.
Proof.
move=> x A; rewrite /= -nbhs_entourageE => -[E entE].
move/(subset_trans (ent_closure entE)) => ExA.
by exists (xsection (split_ent E) x) => //; exists (split_ent E).
Qed.

End completely_regular.

Module completely_regular_uniformity.
Section completely_regular_uniformity.
Context {R : realType} {X : topologicalType}.
Hypothesis crs : completely_regular_space X.

Let X' : uniformType := @sup_topology X {f : X -> R | continuous f}
(fun f => Uniform.class (weak_topology (projT1 f))).

Let completely_regular_nbhsE : @nbhs X X = nbhs_ (@entourage X').
Proof.
rewrite nbhs_entourageE; apply/funext => x; apply/seteqP; split; first last.
apply/cvg_sup => -[f ctsf] U [/= _ [[V /= oV <- /= Vfx]]] /filterS.
by apply; exact/ctsf/open_nbhs_nbhs.
move=> U; wlog oU : U / @open X U.
move=> WH; rewrite nbhsE => -[V [oV Vx /filterS]].
apply; first exact: (@nbhs_filter X').
by apply: WH => //; move: oV; rewrite openE; exact.
move=> /[dup] nUx /nbhs_singleton Ux.
have ufs : uniform_separator [set x] (~` U).
by apply: crs; [exact: open_closedC | exact].
have /uniform_separatorP := ufs => /(_ R)[f [ctsf f01 fx0 fU1]].
rewrite -nbhs_entourageE /entourage /= /sup_ent /= smallest_filter_finI.
pose E := map_pair f @^-1` (fun pq => ball pq.1 1 pq.2).
exists E; first last.
move=> z /= /set_mem; rewrite /E /=.
have -> : f x = 0 by apply: fx0; exists x.
rewrite /ball /= sub0r normrN; apply: contraPP => cUz.
suff -> : f z = 1 by rewrite normr1 ltxx.
by apply: fU1; exists z.
move=> r /= [_]; apply => /=.
pose f' : {classic {f : X -> R | continuous f}} := exist _ f ctsf.
suff /asboolP entE : @entourage (weak_topology f) (f', E).2.
by exists (exist _ (f', E) entE).
exists (fun pq => ball pq.1 1 pq.2) => //=.
by rewrite /entourage /=; exists 1 => /=.
Qed.

Definition type : Type := let _ := completely_regular_nbhsE in X.

#[export] HB.instance Definition _ := Topological.copy type X.
#[export] HB.instance Definition _ := @Nbhs_isUniform.Build
type
(@entourage X')
(@entourage_filter X')
(@entourage_diagonal_subproof X')
(@entourage_inv X')
(@entourage_split_ex X')
completely_regular_nbhsE.
#[export] HB.instance Definition _ := Uniform.on type.

End completely_regular_uniformity.
Module Exports. HB.reexport. End Exports.
End completely_regular_uniformity.
Export completely_regular_uniformity.Exports.

Section locally_compact_uniform.
Context {X : topologicalType} {R : realType}.
Hypothesis lcpt : locally_compact [set: X].
Hypothesis hsdf : hausdorff_space X.

Let opc := @one_point_compactification X.

Lemma one_point_compactification_completely_reg :
completely_regular_space opc.
Proof.
apply: (@normal_completely_regular R).
apply: compact_normal.
exact: one_point_compactification_hausdorff.
exact: one_point_compactification_compact.
by apply: hausdorff_accessible; exact: one_point_compactification_hausdorff.
Qed.

#[local]
HB.instance Definition _ := Uniform.copy opc
(@completely_regular_uniformity.type R _
one_point_compactification_completely_reg).

Let X' := @weak_topology X opc Some.
Lemma nbhs_one_point_compactification_weakE : @nbhs X X = nbhs_ (@entourage X').
Proof. by rewrite nbhs_entourageE one_point_compactification_weak_topology. Qed.

#[local, non_forgetful_inheritance]
HB.instance Definition _ := @Nbhs_isUniform.Build
X
(@entourage X')
(@entourage_filter X')
(@entourage_diagonal_subproof X')
(@entourage_inv X')
(@entourage_split_ex X')
nbhs_one_point_compactification_weakE.

Lemma locally_compact_completely_regular : completely_regular_space X.
Proof. exact: uniform_completely_regular. Qed.

End locally_compact_uniform.

Lemma completely_regular_regular {R : realType} {X : topologicalType} :
completely_regular_space X -> @regular_space X.
Proof.
move=> crsX; pose P' := @completely_regular_uniformity.type R _ crsX.
exact: (@uniform_regular P').
Qed.

Section pseudometric_normal.

Lemma regular_openP {T : topologicalType} (x : T) :
{for x, @regular_space T} <-> forall A, closed A -> ~ A x ->
exists U V : set T, [/\ open U, open V, U x, A `<=` V & U `&` V = set0].
Proof.
split.
move=> + A clA nAx => /(_ (~` A)) [].
by apply: open_nbhs_nbhs; split => //; exact: closed_openC.
move=> U Ux /subsetC; rewrite setCK => AclU; exists (interior U).
move=> U Ux /subsetC; rewrite setCK => AclU; exists U^°.
exists (~` closure U) ; split => //; first exact: open_interior.
exact/closed_openC/closed_closure.
apply/disjoints_subset; rewrite setCK.
exact: (subset_trans (@interior_subset _ _) (@subset_closure _ _)).
move=> + A Ax => /(_ (~` interior A)) []; [|exact|].
move=> + A Ax => /(_ (~` A^°)) []; [|exact|].
exact/open_closedC/open_interior.
move=> U [V] [oU oV Ux /subsetC cAV /disjoints_subset UV]; exists U.
exact/open_nbhs_nbhs.
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70 changes: 70 additions & 0 deletions theories/separation_axioms.v
Original file line number Diff line number Diff line change
Expand Up @@ -257,6 +257,28 @@ Import numFieldTopology.Exports.
Lemma Rhausdorff (R : realFieldType) : hausdorff_space R.
Proof. exact: order_hausdorff. Qed.

Lemma one_point_compactification_hausdorff {X : topologicalType} :
locally_compact [set: X] ->
hausdorff_space X ->
hausdorff_space (one_point_compactification X).
Proof.
move=> lcpt hsdfX [x|] [y|] //=.
- move=> clxy; congr Some; apply: hsdfX => U V Ux Vy.
have [] := clxy (Some @` U) (Some @` V).
by apply: filterS Ux; exact: preimage_image.
by apply: filterS Vy; exact: preimage_image.
by case=> [_|] [] /= [// p /[swap] -[] <- Up] [q /[swap] -[] -> Vp]; exists p.
- have [U] := lcpt x I; rewrite withinET => Ux [cU clU].
case/(_ (Some @` U) (Some @` (~` U) `|` [set None])).
+ exact: one_point_compactification_some_nbhs.
+ by exists U.
+ by move=> [?|] [][]// z /[swap] -[] <- ? []//= [? /[swap] -[] ->].
- have [U] := lcpt y I; rewrite withinET => Uy [cU clU].
case/(_ (Some @` (~` U) `|` [set None]) (Some @` U)); first by exists U.
exact: one_point_compactification_some_nbhs.
by case=> [?|] [] [] //= + [] ? // /[swap] -[] -> => -[? /[swap] -[] <-].
Qed.

Section hausdorff_topologicalType.
Variable T : topologicalType.
Implicit Types x y : T.
Expand Down Expand Up @@ -465,6 +487,54 @@ have /closure_id -> : closed (~` B); first by exact: open_closedC.
by apply/closure_subset/disjoints_subset; rewrite setIC.
Qed.

Lemma compact_normal_local (K : set T) : hausdorff_space T -> compact K ->
forall A : set T, A `<=` K^° -> {for A, normal_space}.
Proof.
move=> hT cptV A AK clA B snAB; have /compact_near_coveringP cvA : compact A.
apply/(subclosed_compact clA cptV)/(subset_trans AK).
exact: interior_subset.
have snbC (U : set T) : Filter (filter_from (set_nbhs U) closure).
apply: filter_from_filter; first by exists setT; apply: filterT.
by move=> P Q sAP sAQ; exists (P `&` Q); [apply filterI|exact: closureI].
have [/(congr1 setC)|/set0P[b0 B0]] := eqVneq (~` B) set0.
by rewrite setCK setC0 => ->; exact: filterT.
have PsnA : ProperFilter (filter_from (set_nbhs (~` B)) closure).
apply: filter_from_proper => ? P.
by exists b0; apply/subset_closure; apply: nbhs_singleton; exact: P.
pose F := powerset_filter_from (filter_from (set_nbhs (~` B)) closure).
have PF : Filter F by exact: powerset_filter_from_filter.
have cvP (x : T) : A x -> \forall x' \near x & i \near F, (~` i) x'.
move=> Ax; case/set_nbhsP : snAB => C [oC AC CB].
have [] := @compact_regular x _ hT cptV _ C; first exact: AK.
by rewrite nbhsE /=; exists C => //; split => //; exact: AC.
move=> D /nbhs_interior nD cDC.
have snBD : filter_from (set_nbhs (~` B)) closure (closure (~` closure D)).
exists (closure (~` closure D)) => [z|].
move=> nBZ; apply: filterS; first exact: subset_closure.
apply: open_nbhs_nbhs; split; first exact/closed_openC/closed_closure.
exact/(subsetC _ nBZ)/(subset_trans cDC).
by have := @closed_closure _ (~` closure D); rewrite closure_id => <-.
near=> y U => /=; have Dy : D^° y by exact: (near nD _).
have UclD : U `<=` closure (~` closure D).
exact: (near (small_set_sub snBD) U).
move=> Uy; have [z [/= + Dz]] := UclD _ Uy _ Dy.
by apply; exact: subset_closure.
case/(_ _ _ _ _ cvP) : cvA => R /= [RA Rmono [U RU] RBx].
have [V /set_nbhsP [W [oW cBW WV] clVU]] := RA _ RU; exists (~` W).
apply/set_nbhsP; exists (~` closure W); split.
- exact/closed_openC/closed_closure.
- by move=> y /(RBx _ RU) + Wy; apply; exact/clVU/(closure_subset WV).
- by apply: subsetC; exact/subset_closure.
have : closed (~` W) by exact: open_closedC.
by rewrite closure_id => <-; exact: subsetCl.
Unshelve. all: by end_near. Qed.

Lemma compact_normal : hausdorff_space T -> compact [set: T] -> normal_space.
Proof.
move=> ? /compact_normal_local + A clA; apply => //.
by move=> z ?; exact: filterT.
Qed.

End set_separations.

Arguments normal_space : clear implicits.
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