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Mathlib.CategoryTheory.Galois.Prorepresentability

Pro-Representability of fiber functors #

We show that any fiber functor is pro-representable, i.e. there exists a pro-object X : I ⥤ C such that F is naturally isomorphic to the colimit of X ⋙ coyoneda.

From this we deduce the canonical isomorphism of Aut F with the limit over the automorphism groups of all Galois objects.

Main definitions #

PointedGaloisObject: the category of pointed Galois objects
PointedGaloisObject.cocone: a cocone on (PointedGaloisObject.incl F).op ≫ coyoneda with point F ⋙ FintypeCat.incl.
autGaloisSystem: the system of automorphism groups indexed by the pointed Galois objects.

Main results #

PointedGaloisObject.isColimit: the cocone PointedGaloisObject.cocone is a colimit cocone.
autMulEquivAutGalois: Aut F is canonically isomorphic to the limit over the automorphism groups of all Galois objects.
FiberFunctor.isPretransitive_of_isConnected: The Aut F action on the fiber of a connected object is transitive.

Implementation details #

The pro-representability statement and the isomorphism of Aut F with the limit over the automorphism groups of all Galois objects naturally forces F to take values in FintypeCat.{u₂} where u₂ is the Hom-universe of C. Since this is used to show that Aut F acts transitively on F.obj X for connected X, we a priori only obtain this result for the mentioned specialized universe setup. To obtain the result for F taking values in an arbitrary FintypeCat.{w}, we postcompose with an equivalence FintypeCat.{w} ≌ FintypeCat.{u₂} and apply the specialized result.

In the following the section Specialized is reserved for the setup where F takes values in FintypeCat.{u₂} and the section General contains results holding for F taking values in an arbitrary FintypeCat.{w}.

References #

[lenstraGSchemes]: H. W. Lenstra. Galois theory for schemes.

structure CategoryTheory.PreGaloisCategory.PointedGaloisObject {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) :

Type (max u₁ u₂ w)

A pointed Galois object is a Galois object with a fixed point of its fiber.

obj : C
The underlying object of C.
pt : (F.obj self.obj).carrier
An element of the fiber of obj.
isGalois : IsGalois self.obj
obj is Galois.

Instances For

instance CategoryTheory.PreGaloisCategory.PointedGaloisObject.instCoeDep {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) (X : PointedGaloisObject F) :

CoeDep (PointedGaloisObject F) X C

Equations

CategoryTheory.PreGaloisCategory.PointedGaloisObject.instCoeDep F X = { coe := X.obj }

structure CategoryTheory.PreGaloisCategory.PointedGaloisObject.Hom {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] {F : Functor C FintypeCat} (A B : PointedGaloisObject F) :

Type u₂

The type of homomorphisms between two pointed Galois objects. This is a homomorphism of the underlying objects of C that maps the distinguished points to each other.

val : A.obj ⟶ B.obj
The underlying homomorphism of C.
comp : F.map self.val A.pt = B.pt
The distinguished point of A is mapped to the distinguished point of B.

Instances For

theorem CategoryTheory.PreGaloisCategory.PointedGaloisObject.Hom.ext {C : Type u₁} {inst✝ : Category.{u₂, u₁} C} {inst✝¹ : GaloisCategory C} {F : Functor C FintypeCat} {A B : PointedGaloisObject F} {x y : A.Hom B} (val : x.val = y.val) :

x = y

theorem CategoryTheory.PreGaloisCategory.PointedGaloisObject.Hom.ext_iff {C : Type u₁} {inst✝ : Category.{u₂, u₁} C} {inst✝¹ : GaloisCategory C} {F : Functor C FintypeCat} {A B : PointedGaloisObject F} {x y : A.Hom B} :

x = y ↔ x.val = y.val

instance CategoryTheory.PreGaloisCategory.PointedGaloisObject.instCategory {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) :

Category.{u₂, max (max w u₂) u₁} (PointedGaloisObject F)

The category of pointed Galois objects.

Equations

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

instance CategoryTheory.PreGaloisCategory.PointedGaloisObject.instCoeHomHomObj {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) {A B : PointedGaloisObject F} :

Coe (A.Hom B) (A.obj ⟶ B.obj)

Equations

CategoryTheory.PreGaloisCategory.PointedGaloisObject.instCoeHomHomObj F = { coe := fun (f : A.Hom B) => f.val }

theorem CategoryTheory.PreGaloisCategory.PointedGaloisObject.hom_ext {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] {F : Functor C FintypeCat} {A B : PointedGaloisObject F} {f g : A ⟶ B} (h : f.val = g.val) :

f = g

theorem CategoryTheory.PreGaloisCategory.PointedGaloisObject.hom_ext_iff {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] {F : Functor C FintypeCat} {A B : PointedGaloisObject F} {f g : A ⟶ B} :

f = g ↔ f.val = g.val

@[simp]

theorem CategoryTheory.PreGaloisCategory.PointedGaloisObject.id_val {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] {F : Functor C FintypeCat} (A : PointedGaloisObject F) :

(CategoryStruct.id A).val = CategoryStruct.id A.obj

@[simp]

theorem CategoryTheory.PreGaloisCategory.PointedGaloisObject.comp_val {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] {F : Functor C FintypeCat} {A B C✝ : PointedGaloisObject F} (f : A ⟶ B) (g : B ⟶ C✝) :

(CategoryStruct.comp f g).val = CategoryStruct.comp f.val g.val

theorem CategoryTheory.PreGaloisCategory.PointedGaloisObject.comp_val_assoc {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] {F : Functor C FintypeCat} {A B C✝ : PointedGaloisObject F} (f : A ⟶ B) (g : B ⟶ C✝) {Z : C} (h : C✝.obj ⟶ Z) :

CategoryStruct.comp (CategoryStruct.comp f g).val h = CategoryStruct.comp f.val (CategoryStruct.comp g.val h)

def CategoryTheory.PreGaloisCategory.PointedGaloisObject.incl {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) :

Functor (PointedGaloisObject F) C

The canonical functor from pointed Galois objects to C.

Equations

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

Instances For

@[simp]

theorem CategoryTheory.PreGaloisCategory.PointedGaloisObject.incl_obj {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) (A : PointedGaloisObject F) :

(incl F).obj A = A.obj

@[simp]

theorem CategoryTheory.PreGaloisCategory.PointedGaloisObject.incl_map {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) {A B : PointedGaloisObject F} (f : A ⟶ B) :

(incl F).map f = f.val

def CategoryTheory.PreGaloisCategory.PointedGaloisObject.cocone {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) :

Limits.Cocone ((incl F).op.comp coyoneda)

F ⋙ FintypeCat.incl as a cocone over (can F).op ⋙ coyoneda. This is a colimit cocone (see PreGaloisCategory.isColimìt)

Equations

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

Instances For

@[simp]

theorem CategoryTheory.PreGaloisCategory.PointedGaloisObject.cocone_app {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) (A : PointedGaloisObject F) (B : C) (f : A.obj ⟶ B) :

((cocone F).ι.app (Opposite.op A)).app B f = F.map f A.pt

instance CategoryTheory.PreGaloisCategory.PointedGaloisObject.instIsCofilteredOrEmpty {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] :

IsCofilteredOrEmpty (PointedGaloisObject F)

The category of pointed Galois objects is cofiltered.

noncomputable def CategoryTheory.PreGaloisCategory.PointedGaloisObject.isColimit {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] :

Limits.IsColimit (cocone F)

cocone F is a colimit cocone, i.e. F is pro-represented by incl F.

Equations

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

Instances For

instance CategoryTheory.PreGaloisCategory.PointedGaloisObject.instHasColimitOppositeFunctorTypeCompOpInclCoyoneda {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] :

Limits.HasColimit ((incl F).op.comp coyoneda)

noncomputable def CategoryTheory.PreGaloisCategory.autGaloisSystem {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) :

Functor (PointedGaloisObject F) Grp

The diagram sending each pointed Galois object to its automorphism group as an object of C.

Equations

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

Instances For

@[simp]

theorem CategoryTheory.PreGaloisCategory.autGaloisSystem_map {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) {A B : PointedGaloisObject F} (f : A ⟶ B) :

(autGaloisSystem F).map f = Grp.ofHom (autMapHom f.val)

@[simp]

theorem CategoryTheory.PreGaloisCategory.autGaloisSystem_obj_coe {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) (A : PointedGaloisObject F) :

↑((autGaloisSystem F).obj A) = Aut A.obj

noncomputable def CategoryTheory.PreGaloisCategory.AutGalois {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) :

Type (max u₁ u₂)

The limit of autGaloisSystem.

Equations

CategoryTheory.PreGaloisCategory.AutGalois F = ↑((CategoryTheory.PreGaloisCategory.autGaloisSystem F).comp (CategoryTheory.forget Grp)).sections

Instances For

noncomputable instance CategoryTheory.PreGaloisCategory.instGroupAutGalois {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) :

Group (AutGalois F)

Equations

CategoryTheory.PreGaloisCategory.instGroupAutGalois F = inferInstanceAs (Group ↑((CategoryTheory.PreGaloisCategory.autGaloisSystem F).comp (CategoryTheory.forget Grp)).sections)

noncomputable def CategoryTheory.PreGaloisCategory.AutGalois.π {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) (A : PointedGaloisObject F) :

AutGalois F →* Aut A.obj

The canonical projection from AutGalois F to the C-automorphism group of each pointed Galois object.

Equations

CategoryTheory.PreGaloisCategory.AutGalois.π F A = Grp.sectionsπMonoidHom (CategoryTheory.PreGaloisCategory.autGaloisSystem F) A

Instances For

theorem CategoryTheory.PreGaloisCategory.AutGalois.π_apply {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) (A : PointedGaloisObject F) (x : AutGalois F) :

(π F A) x = ↑x A

theorem CategoryTheory.PreGaloisCategory.autGaloisSystem_map_surjective {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) ⦃A B : PointedGaloisObject F⦄ (f : A ⟶ B) :

Function.Surjective ⇑(ConcreteCategory.hom ((autGaloisSystem F).map f))

theorem CategoryTheory.PreGaloisCategory.AutGalois.ext {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) {f g : AutGalois F} (h : ∀ (A : PointedGaloisObject F), (π F A) f = (π F A) g) :

f = g

Equality of elements of AutGalois F can be checked on the projections on each pointed Galois object.

theorem CategoryTheory.PreGaloisCategory.AutGalois.π_surjective {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] (A : PointedGaloisObject F) :

Function.Surjective ⇑(π F A)

autGalois.π is surjective for every pointed Galois object.

Isomorphism between `Aut F` and `AutGalois F` #

In this section we establish the isomorphism between the automorphism group of F and the limit over the automorphism groups of all Galois objects.

We first establish the isomorphism between End F and AutGalois F, from which we deduce that End F is a group, hence End F = Aut F. The isomorphism is built in multiple steps:

endEquivSectionsFibers : End F ≅ (incl F ⋙ F').sections: the endomorphisms of F are isomorphic to the limit over F.obj A for all Galois objects A. This is obtained as the composition (slightly simplified):

End F ≅ (colimit ((incl F).op ⋙ coyoneda) ⟶ F) ≅ (incl F ⋙ F).sections

Where the first isomorphism is induced from the pro-representability of F and the second one from the pro-coyoneda lemma.
endEquivAutGalois : End F ≅ AutGalois F: this is the composition of endEquivSectionsFibers with:

(incl F ⋙ F).sections ≅ (autGaloisSystem F ⋙ forget Grp).sections

which is induced from the level-wise equivalence Aut A ≃ F.obj A for a Galois object A.

noncomputable def CategoryTheory.PreGaloisCategory.endEquivSectionsFibers {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] :

End F ≃ ↑((PointedGaloisObject.incl F).comp (F.comp FintypeCat.incl)).sections

The endomorphisms of F are isomorphic to the limit over the fibers of F on all Galois objects.

Equations

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

Instances For

@[simp]

theorem CategoryTheory.PreGaloisCategory.endEquivSectionsFibers_π {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] (f : End F) (A : PointedGaloisObject F) :

↑((endEquivSectionsFibers F) f) A = f.app A.obj A.pt

noncomputable def CategoryTheory.PreGaloisCategory.autIsoFibers {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] :

(autGaloisSystem F).comp (forget Grp) ≅ (PointedGaloisObject.incl F).comp (F.comp FintypeCat.incl)

Functorial isomorphism Aut A ≅ F.obj A for Galois objects A.

Equations

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

Instances For

theorem CategoryTheory.PreGaloisCategory.autIsoFibers_inv_app {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] (A : PointedGaloisObject F) (b : (F.obj A.obj).carrier) :

(autIsoFibers F).inv.app A b = (evaluationEquivOfIsGalois F A.obj A.pt).symm b

noncomputable def CategoryTheory.PreGaloisCategory.endEquivAutGalois {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] :

End F ≃ AutGalois F

The equivalence between endomorphisms of F and the limit over the automorphism groups of all Galois objects.

Equations

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

Instances For

theorem CategoryTheory.PreGaloisCategory.endEquivAutGalois_π {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] (f : End F) (A : PointedGaloisObject F) :

F.map ((AutGalois.π F A) ((endEquivAutGalois F) f)).hom A.pt = f.app A.obj A.pt

@[simp]

theorem CategoryTheory.PreGaloisCategory.endEquivAutGalois_mul {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] (f g : End F) :

(endEquivAutGalois F) (CategoryStruct.comp g f) = (endEquivAutGalois F) g * (endEquivAutGalois F) f

noncomputable def CategoryTheory.PreGaloisCategory.endMulEquivAutGalois {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] :

End F ≃* (AutGalois F)ᵐᵒᵖ

The monoid isomorphism between endomorphisms of F and the (multiplicative opposite of the) limit of automorphism groups of all Galois objects.

Equations

CategoryTheory.PreGaloisCategory.endMulEquivAutGalois F = { toEquiv := (CategoryTheory.PreGaloisCategory.endEquivAutGalois F).trans MulOpposite.opEquiv, map_mul' := ⋯ }

Instances For

theorem CategoryTheory.PreGaloisCategory.endMulEquivAutGalois_pi {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] (f : End F) (A : PointedGaloisObject F) :

F.map ((AutGalois.π F A) (MulOpposite.unop ((endMulEquivAutGalois F) f))).hom A.pt = f.app A.obj A.pt

theorem CategoryTheory.PreGaloisCategory.FibreFunctor.end_isUnit {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] (f : End F) :

Any endomorphism of a fiber functor is a unit.

instance CategoryTheory.PreGaloisCategory.FibreFunctor.end_isIso {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] (f : End F) :

Any endomorphism of a fiber functor is an isomorphism.

noncomputable def CategoryTheory.PreGaloisCategory.autMulEquivAutGalois {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] :

Aut F ≃* (AutGalois F)ᵐᵒᵖ

The automorphism group of F is multiplicatively isomorphic to (the multiplicative opposite of) the limit over the automorphism groups of the Galois objects.

Equations

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

Instances For

theorem CategoryTheory.PreGaloisCategory.autMulEquivAutGalois_π {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] (f : Aut F) (A : C) [IsGalois A] (a : (F.obj A).carrier) :

F.map ((AutGalois.π F { obj := A, pt := a, isGalois := ⋯ }) (MulOpposite.unop ((autMulEquivAutGalois F) f))).hom a = f.hom.app A a

@[simp]

theorem CategoryTheory.PreGaloisCategory.autMulEquivAutGalois_symm_app {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] (x : AutGalois F) (A : C) [IsGalois A] (a : (F.obj A).carrier) :

((autMulEquivAutGalois F).symm { unop' := x }).hom.app A a = F.map ((AutGalois.π F { obj := A, pt := a, isGalois := ⋯ }) x).hom a

theorem CategoryTheory.PreGaloisCategory.FiberFunctor.isPretransitive_of_isGalois {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] (X : C) [IsGalois X] :

MulAction.IsPretransitive (Aut F) (F.obj X).carrier

The Aut F action on the fiber of a Galois object is transitive. See pretransitive_of_isConnected for the same result for connected objects.

instance CategoryTheory.PreGaloisCategory.FiberFunctor.isPretransitive_of_isConnected {C : Type u₁} [Category.{u₂, u₁} C] [GaloisCategory C] (F : Functor C FintypeCat) [FiberFunctor F] (X : C) [IsConnected X] :

MulAction.IsPretransitive (Aut F) (F.obj X).carrier

The Aut F action on the fiber of a connected object is transitive.