Documentation

Mathlib.Topology.Category.Profinite.Basic

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.

The category Profinite is defined using the structure CompHausLike. See the file CompHausLike.Basic for more information.

TODO #

Define procategories and prove that Profinite is equivalent to Pro (FintypeCat).

Tags #

profinite

@[reducible, inline]

abbrev Profinite :

Type (u_1 + 1)

The type of profinite topological spaces.

Equations

Profinite = CompHausLike fun (X : TopCat) => TotallyDisconnectedSpace ↑X

Instances For

instance Profinite.instHasPropTotallyDisconnectedSpaceCarrier (X : Type u_1) [TopologicalSpace X] [TotallyDisconnectedSpace X] :

CompHausLike.HasProp (fun (Y : TopCat) => TotallyDisconnectedSpace ↑Y) X

@[reducible, inline]

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

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

Equations

Profinite.of X = CompHausLike.of (fun (X : TopCat) => TotallyDisconnectedSpace ↑X) X

Instances For

instance Profinite.instInhabited :

Inhabited Profinite

Equations

Profinite.instInhabited = { default := Profinite.of PEmpty.{?u.2 + 1} }

instance Profinite.instTotallyDisconnectedSpaceCarrierToTop {X : Profinite} :

TotallyDisconnectedSpace ↑X.toTop

@[reducible, inline]

abbrev profiniteToCompHaus :

CategoryTheory.Functor Profinite CompHaus

The fully faithful embedding of Profinite in CompHaus.

Equations

profiniteToCompHaus = compHausLikeToCompHaus fun (X : TopCat) => TotallyDisconnectedSpace ↑X

Instances For

instance instTotallyDisconnectedSpaceCarrierToTopTrueObjProfiniteCompHausProfiniteToCompHaus {X : Profinite} :

TotallyDisconnectedSpace ↑(profiniteToCompHaus.obj X).toTop

@[reducible, inline]

abbrev Profinite.toTopCat :

CategoryTheory.Functor Profinite TopCat

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

Equations

Profinite.toTopCat = CompHausLike.compHausLikeToTop fun (X : TopCat) => TotallyDisconnectedSpace ↑X

Instances For

def CompHaus.toProfiniteObj (X : CompHaus) :

(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.

Stacks Tag 0900

Equations

X.toProfiniteObj = { toTop := TopCat.of (ConnectedComponents ↑X.toTop), is_compact := ⋯, is_hausdorff := ⋯, prop := ⋯ }

Instances For

def Profinite.toCompHausEquivalence (X : CompHaus) (Y : Profinite) :

(X.toProfiniteObj ⟶ Y) ≃ (X ⟶ profiniteToCompHaus.obj Y)

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

Equations

One or more equations did not get rendered due to their size.

Instances For

def CompHaus.toProfinite :

CategoryTheory.Functor CompHaus Profinite

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

Equations

CompHaus.toProfinite = CategoryTheory.Adjunction.leftAdjointOfEquiv Profinite.toCompHausEquivalence CompHaus.toProfinite._proof_20

Instances For

theorem CompHaus.toProfinite_obj' (X : CompHaus) :

↑(toProfinite.obj X).toTop = ConnectedComponents ↑X.toTop

def FintypeCat.botTopology (A : FintypeCat) :

TopologicalSpace A.carrier

Finite types are given the discrete topology.

Equations

A.botTopology = ⊥

Instances For

theorem FintypeCat.discreteTopology (A : FintypeCat) :

DiscreteTopology A.carrier

def FintypeCat.toProfinite :

CategoryTheory.Functor FintypeCat Profinite

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

Equations

One or more equations did not get rendered due to their size.

Instances For

theorem FintypeCat.toProfinite_map_hom_apply {X✝ Y✝ : FintypeCat} (f : X✝ ⟶ Y✝) (a✝ : X✝.carrier) :

(TopCat.Hom.hom (toProfinite.map f)) a✝ = f a✝

def FintypeCat.toProfiniteFullyFaithful :

toProfinite.FullyFaithful

FintypeCat.toLightProfinite is fully faithful.

Equations

One or more equations did not get rendered due to their size.

Instances For

instance instFaithfulFintypeCatProfiniteToProfinite :

FintypeCat.toProfinite.Faithful

instance instFullFintypeCatProfiniteToProfinite :

FintypeCat.toProfinite.Full

instance instFintypeCarrierToTopTotallyDisconnectedSpaceObjFintypeCatProfiniteToProfinite (X : FintypeCat) :

Fintype ↑(FintypeCat.toProfinite.obj X).toTop

Equations

instFintypeCarrierToTopTotallyDisconnectedSpaceObjFintypeCatProfiniteToProfinite X = inferInstanceAs (Fintype X.carrier)

instance instFintypeCarrierToTopTotallyDisconnectedSpaceOfCarrier (X : FintypeCat) :

Fintype ↑(Profinite.of X.carrier).toTop

Equations

instFintypeCarrierToTopTotallyDisconnectedSpaceOfCarrier X = inferInstanceAs (Fintype X.carrier)

def Profinite.limitCone {J : Type v} [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.

Equations

One or more equations did not get rendered due to their size.

Instances For

def Profinite.limitConeIsLimit {J : Type v} [CategoryTheory.SmallCategory J] (F : CategoryTheory.Functor J Profinite) :

CategoryTheory.Limits.IsLimit (limitCone F)

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

Equations

One or more equations did not get rendered due to their size.

Instances For

def Profinite.toProfiniteAdjToCompHaus :

CompHaus.toProfinite ⊣ profiniteToCompHaus

The adjunction between CompHaus.to_Profinite and Profinite.to_CompHaus

Equations

Profinite.toProfiniteAdjToCompHaus = CategoryTheory.Adjunction.adjunctionOfEquivLeft Profinite.toCompHausEquivalence CompHaus.toProfinite._proof_20

Instances For

instance Profinite.toCompHaus.reflective :

CategoryTheory.Reflective profiniteToCompHaus

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

Equations

One or more equations did not get rendered due to their size.

noncomputable instance Profinite.toCompHaus.createsLimits :

CategoryTheory.CreatesLimits profiniteToCompHaus

Equations

Profinite.toCompHaus.createsLimits = CategoryTheory.monadicCreatesLimits profiniteToCompHaus

noncomputable instance Profinite.toTopCat.reflective :

CategoryTheory.Reflective toTopCat

Equations

Profinite.toTopCat.reflective = CategoryTheory.Reflective.comp profiniteToCompHaus compHausToTop

noncomputable instance Profinite.toTopCat.createsLimits :

CategoryTheory.CreatesLimits toTopCat

Equations

Profinite.toTopCat.createsLimits = CategoryTheory.monadicCreatesLimits Profinite.toTopCat

instance Profinite.hasLimits :

CategoryTheory.Limits.HasLimits Profinite

instance Profinite.hasColimits :

CategoryTheory.Limits.HasColimits Profinite

instance Profinite.forget_preservesLimits :

CategoryTheory.Limits.PreservesLimits (CategoryTheory.forget Profinite)

theorem Profinite.epi_iff_surjective {X Y : Profinite} (f : X ⟶ Y) :

CategoryTheory.Epi f ↔ Function.Surjective ⇑(CategoryTheory.ConcreteCategory.hom f)

def Profinite.pi {α : Type u} (β : α → Profinite) :

The pi-type of profinite spaces is profinite.

Equations

Profinite.pi β = Profinite.of ((a : α) → ↑(β a).toTop)

Instances For