The category of Profinite Types

We construct the category of profinite topological spaces, often called profinite sets -- perhaps they could be called profinite types in Lean.

The type of profinite topological spaces is called Profinite. It has a category instance and is a fully faithful subcategory of TopCat. The fully faithful functor is called Profinite.toTop.

Implementation notes

A profinite type is defined to be a topological space which is compact, Hausdorff and totally disconnected.

TODO

0. Link to category of projective limits of finite discrete sets.
1. finite coproducts
2. Clausen/Scholze topology on the category Profinite.

Tags

profinite

structure Profinite : Type (u_1 + 1)

• toCompHaus : CompHaus

  The underlying compact Hausdorff space of a profinite space.

• IsTotallyDisconnected : TotallyDisconnectedSpace ↑s.toCompHaus.toTop

  A profinite space is totally disconnected.

The type of profinite topological spaces.

def Profinite.of (X : Type u_1) [TopologicalSpace X] [CompactSpace X] [T2Space X] [TotallyDisconnectedSpace X] : Profinite

Construct a term of Profinite from a type endowed with the structure of a compact, Hausdorff and totally disconnected topological space.

instance Profinite.instInhabitedProfinite : Inhabited Profinite

instance Profinite.category : CategoryTheory.Category.{u_1, u_1 + 1} Profinite

instance Profinite.concreteCategory : CategoryTheory.ConcreteCategory Profinite

instance Profinite.hasForget₂ : CategoryTheory.HasForget₂ Profinite TopCat

instance Profinite.instCoeSortProfiniteType : CoeSort Profinite (Type u_1)

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theorem Profinite.forget_ContinuousMap_mk {X : Profinite} {Y : Profinite} (f : ↑X.toCompHaus.toTop → ↑Y.toCompHaus.toTop) (hf : Continuous f) : (CategoryTheory.forget Profinite).map (ContinuousMap.mk f) = f

instance Profinite.instTotallyDisconnectedSpaceαTopologicalSpaceToTopToCompHausTopologicalSpace_coe {X : Profinite} : TotallyDisconnectedSpace ↑X.toCompHaus.toTop

instance Profinite.instTopologicalSpaceObjProfiniteToQuiverToCategoryStructCategoryTypeTypesToPrefunctorForgetConcreteCategory {X : Profinite} : TopologicalSpace ((CategoryTheory.forget Profinite).obj X)

instance Profinite.instTotallyDisconnectedSpaceObjProfiniteToQuiverToCategoryStructCategoryTypeTypesToPrefunctorForgetConcreteCategoryInstTopologicalSpaceObjProfiniteToQuiverToCategoryStructCategoryTypeTypesToPrefunctorForgetConcreteCategory {X : Profinite} : TotallyDisconnectedSpace ((CategoryTheory.forget Profinite).obj X)

instance Profinite.instCompactSpaceObjProfiniteToQuiverToCategoryStructCategoryTypeTypesToPrefunctorForgetConcreteCategoryInstTopologicalSpaceObjProfiniteToQuiverToCategoryStructCategoryTypeTypesToPrefunctorForgetConcreteCategory {X : Profinite} : CompactSpace ((CategoryTheory.forget Profinite).obj X)

instance Profinite.instT2SpaceObjProfiniteToQuiverToCategoryStructCategoryTypeTypesToPrefunctorForgetConcreteCategoryInstTopologicalSpaceObjProfiniteToQuiverToCategoryStructCategoryTypeTypesToPrefunctorForgetConcreteCategory {X : Profinite} : T2Space ((CategoryTheory.forget Profinite).obj X)

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theorem Profinite.coe_id (X : Profinite) : CategoryTheory.CategoryStruct.id ((CategoryTheory.forget Profinite).obj X) = id

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theorem Profinite.coe_comp {X : Profinite} {Y : Profinite} {Z : Profinite} (f : X ⟶ Y) (g : Y ⟶ Z) : CategoryTheory.CategoryStruct.comp ((CategoryTheory.forget Profinite).map f) ((CategoryTheory.forget Profinite).map g) = ↑g ∘ ↑f

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theorem profiniteToCompHaus_obj (self : Profinite) : profiniteToCompHaus.obj self = self.toCompHaus

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theorem profiniteToCompHaus_map : ∀ {X Y : CategoryTheory.InducedCategory CompHaus Profinite.toCompHaus} (f : X ⟶ Y), profiniteToCompHaus.map f = f

def profiniteToCompHaus : CategoryTheory.Functor Profinite CompHaus

The fully faithful embedding of Profinite in CompHaus.

instance instFullProfiniteCategoryCompHausCategoryProfiniteToCompHaus : CategoryTheory.Full profiniteToCompHaus

instance instFaithfulProfiniteCategoryCompHausCategoryProfiniteToCompHaus : CategoryTheory.Faithful profiniteToCompHaus

instance instTotallyDisconnectedSpaceαTopologicalSpaceToTopObjProfiniteToQuiverToCategoryStructCategoryCompHausCategoryToPrefunctorProfiniteToCompHausTopologicalSpace_coe {X : Profinite} : TotallyDisconnectedSpace ↑(profiniteToCompHaus.obj X).toTop

@[simp]

theorem Profinite.toTopCat_obj (X : CategoryTheory.InducedCategory CompHaus Profinite.toCompHaus) : Profinite.toTopCat.obj X = X.toCompHaus.toTop

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theorem Profinite.toTopCat_map : ∀ {X Y : CategoryTheory.InducedCategory TopCat fun X => X.toCompHaus.toTop} (f : X ⟶ Y), Profinite.toTopCat.map f = f

def Profinite.toTopCat : CategoryTheory.Functor Profinite TopCat

The fully faithful embedding of Profinite in TopCat. This is definitionally the same as the obvious composite.

instance instFullProfiniteCategoryTopCatInstTopCatLargeCategoryToTopCat : CategoryTheory.Full Profinite.toTopCat

instance instFaithfulProfiniteCategoryTopCatInstTopCatLargeCategoryToTopCat : CategoryTheory.Faithful Profinite.toTopCat

@[simp]

theorem Profinite.to_compHausToTopCat : CategoryTheory.Functor.comp profiniteToCompHaus compHausToTop = Profinite.toTopCat

def CompHaus.toProfiniteObj (X : CompHaus) : Profinite

(Implementation) The object part of the connected_components functor from compact Hausdorff spaces to Profinite spaces, given by quotienting a space by its connected components. See: https://stacks.math.columbia.edu/tag/0900

def Profinite.toCompHausEquivalence (X : CompHaus) (Y : Profinite) : (CompHaus.toProfiniteObj X ⟶ Y) ≃ (X ⟶ profiniteToCompHaus.obj Y)

(Implementation) The bijection of homsets to establish the reflective adjunction of Profinite spaces in compact Hausdorff spaces.

def CompHaus.toProfinite : CategoryTheory.Functor CompHaus Profinite

The connected_components functor from compact Hausdorff spaces to profinite spaces, left adjoint to the inclusion functor.

theorem CompHaus.toProfinite_obj' (X : CompHaus) : ↑(CompHaus.toProfinite.obj X).toCompHaus.toTop = ConnectedComponents ↑X.toTop

def FintypeCat.botTopology (A : FintypeCat) : TopologicalSpace ↑A

Finite types are given the discrete topology.

theorem FintypeCat.discreteTopology (A : FintypeCat) : DiscreteTopology ↑A

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theorem FintypeCat.toProfinite_map_apply : ∀ {X Y : FintypeCat} (f : X ⟶ Y) (a : ↑X), ↑(FintypeCat.toProfinite.map f) a = f a

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theorem FintypeCat.toProfinite_obj_toCompHaus_toTop_str_IsOpen (A : FintypeCat) (u : Set ↑A) : TopologicalSpace.IsOpen u = (u ∈ ⊤)

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theorem FintypeCat.toProfinite_obj_toCompHaus_toTop_α (A : FintypeCat) : ↑(FintypeCat.toProfinite.obj A).toCompHaus.toTop = ↑A

def FintypeCat.toProfinite : CategoryTheory.Functor FintypeCat Profinite

The natural functor from Fintype to Profinite, endowing a finite type with the discrete topology.

def Profinite.limitCone {J : Type u} [CategoryTheory.SmallCategory J] (F : CategoryTheory.Functor J Profinite) : CategoryTheory.Limits.Cone F

An explicit limit cone for a functor F : J ⥤ Profinite, defined in terms of CompHaus.limitCone, which is defined in terms of TopCat.limitCone.

def Profinite.limitConeIsLimit {J : Type u} [CategoryTheory.SmallCategory J] (F : CategoryTheory.Functor J Profinite) : CategoryTheory.Limits.IsLimit (Profinite.limitCone F)

The limit cone Profinite.limitCone F is indeed a limit cone.

def Profinite.toProfiniteAdjToCompHaus : CompHaus.toProfinite ⊣ profiniteToCompHaus

The adjunction between CompHaus.to_Profinite and Profinite.to_CompHaus

instance Profinite.toCompHaus.reflective : CategoryTheory.Reflective profiniteToCompHaus

The category of profinite sets is reflective in the category of compact Hausdorff spaces

noncomputable instance Profinite.toCompHaus.createsLimits : CategoryTheory.CreatesLimits profiniteToCompHaus

noncomputable instance Profinite.toTopCat.reflective : CategoryTheory.Reflective Profinite.toTopCat

noncomputable instance Profinite.toTopCat.createsLimits : CategoryTheory.CreatesLimits Profinite.toTopCat

instance Profinite.hasLimits : CategoryTheory.Limits.HasLimits Profinite

instance Profinite.hasColimits : CategoryTheory.Limits.HasColimits Profinite

noncomputable instance Profinite.forgetPreservesLimits : CategoryTheory.Limits.PreservesLimits (CategoryTheory.forget Profinite)

theorem Profinite.isClosedMap {X : Profinite} {Y : Profinite} (f : X ⟶ Y) : IsClosedMap ↑f

Any morphism of profinite spaces is a closed map.

theorem Profinite.isIso_of_bijective {X : Profinite} {Y : Profinite} (f : X ⟶ Y) (bij : Function.Bijective ↑f) : CategoryTheory.IsIso f

Any continuous bijection of profinite spaces induces an isomorphism.

noncomputable def Profinite.isoOfBijective {X : Profinite} {Y : Profinite} (f : X ⟶ Y) (bij : Function.Bijective ↑f) : X ≅ Y

Any continuous bijection of profinite spaces induces an isomorphism.

instance Profinite.forget_reflectsIsomorphisms : CategoryTheory.ReflectsIsomorphisms (CategoryTheory.forget Profinite)

@[simp]

theorem Profinite.isoOfHomeo_hom {X : Profinite} {Y : Profinite} (f : ↑X.toCompHaus.toTop ≃ₜ ↑Y.toCompHaus.toTop) : (Profinite.isoOfHomeo f).hom = ContinuousMap.mk ↑f

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theorem Profinite.isoOfHomeo_inv {X : Profinite} {Y : Profinite} (f : ↑X.toCompHaus.toTop ≃ₜ ↑Y.toCompHaus.toTop) : (Profinite.isoOfHomeo f).inv = CategoryTheory.inv (ContinuousMap.mk ↑f)

noncomputable def Profinite.isoOfHomeo {X : Profinite} {Y : Profinite} (f : ↑X.toCompHaus.toTop ≃ₜ ↑Y.toCompHaus.toTop) : X ≅ Y

Construct an isomorphism from a homeomorphism.

@[simp]

theorem Profinite.homeoOfIso_symm_apply {X : Profinite} {Y : Profinite} (f : X ≅ Y) (a : (CategoryTheory.forget CompHaus).obj Y.toCompHaus) : ↑(Homeomorph.symm (Profinite.homeoOfIso f)) a = ↑f.inv a

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theorem Profinite.homeoOfIso_apply {X : Profinite} {Y : Profinite} (f : X ≅ Y) (a : (CategoryTheory.forget CompHaus).obj X.toCompHaus) : ↑(Profinite.homeoOfIso f) a = ↑f.hom a

def Profinite.homeoOfIso {X : Profinite} {Y : Profinite} (f : X ≅ Y) : ↑X.toCompHaus.toTop ≃ₜ ↑Y.toCompHaus.toTop

Construct a homeomorphism from an isomorphism.

@[simp]

theorem Profinite.isoEquivHomeo_symm_apply_inv {X : Profinite} {Y : Profinite} (f : ↑X.toCompHaus.toTop ≃ₜ ↑Y.toCompHaus.toTop) : (↑Profinite.isoEquivHomeo.symm f).inv = CategoryTheory.inv (ContinuousMap.mk ↑f)

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theorem Profinite.isoEquivHomeo_apply_apply {X : Profinite} {Y : Profinite} (f : X ≅ Y) (a : (CategoryTheory.forget CompHaus).obj X.toCompHaus) : ↑(↑Profinite.isoEquivHomeo f) a = ↑f.hom a

@[simp]

theorem Profinite.isoEquivHomeo_apply_symm_apply {X : Profinite} {Y : Profinite} (f : X ≅ Y) (a : (CategoryTheory.forget CompHaus).obj Y.toCompHaus) : ↑(Homeomorph.symm (↑Profinite.isoEquivHomeo f)) a = ↑f.inv a

@[simp]

theorem Profinite.isoEquivHomeo_symm_apply_hom_apply {X : Profinite} {Y : Profinite} (f : ↑X.toCompHaus.toTop ≃ₜ ↑Y.toCompHaus.toTop) (a : ↑X.toCompHaus.toTop) : ↑(↑Profinite.isoEquivHomeo.symm f).hom a = ↑f a

noncomputable def Profinite.isoEquivHomeo {X : Profinite} {Y : Profinite} : (X ≅ Y) ≃ (↑X.toCompHaus.toTop ≃ₜ ↑Y.toCompHaus.toTop)

The equivalence between isomorphisms in Profinite and homeomorphisms of topological spaces.

theorem Profinite.epi_iff_surjective {X : Profinite} {Y : Profinite} (f : X ⟶ Y) : CategoryTheory.Epi f ↔ Function.Surjective ↑f

instance Profinite.instEpiCompHausCategoryToCompHaus {X : Profinite} {Y : Profinite} (f : X ⟶ Y) [CategoryTheory.Epi f] : CategoryTheory.Epi f

instance Profinite.instEpiProfiniteCategory {X : Profinite} {Y : Profinite} (f : X ⟶ Y) [CategoryTheory.Epi f] : CategoryTheory.Epi f

theorem Profinite.mono_iff_injective {X : Profinite} {Y : Profinite} (f : X ⟶ Y) : CategoryTheory.Mono f ↔ Function.Injective ↑f