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 objectsPointedGaloisObject.cocone
: a cocone on(PointedGaloisObject.incl F).op ≫ coyoneda
with pointF ⋙ FintypeCat.incl
.autGaloisSystem
: the system of automorphism groups indexed by the pointed Galois objects.
Main results #
PointedGaloisObject.isColimit
: the coconePointedGaloisObject.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
: TheAut F
action on the fiber of a connected object is transitive.
References #
- [lenstraGSchemes]: H. W. Lenstra. Galois theory for schemes.
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)
An element of the fiber of
obj
. - isGalois : CategoryTheory.PreGaloisCategory.IsGalois self.obj
obj
is Galois.
Instances For
obj
is Galois.
Equations
- CategoryTheory.PreGaloisCategory.PointedGaloisObject.instCoeDep F X = { coe := X.obj }
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 ofB
.
Instances For
The distinguished point of A
is mapped to the distinguished point of B
.
The category of pointed Galois objects.
Equations
- CategoryTheory.PreGaloisCategory.PointedGaloisObject.instCoeHomHomObj F = { coe := fun (f : A.Hom B) => f.val }
The category of pointed Galois objects is cofiltered.
Equations
- ⋯ = ⋯
The canonical functor from pointed Galois objects to C
.
Equations
- One or more equations did not get rendered due to their size.
Instances For
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
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
Equations
- ⋯ = ⋯
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
The limit of autGaloisSystem
.
Equations
- CategoryTheory.PreGaloisCategory.AutGalois F = ↑((CategoryTheory.PreGaloisCategory.autGaloisSystem F).comp (CategoryTheory.forget Grp)).sections
Instances For
Equations
The canonical projection from AutGalois F
to the C
-automorphism group of each
pointed Galois object.
Equations
Instances For
autGalois.π
is surjective for every pointed Galois object.
Equality of elements of AutGalois F
can be checked on the projections on each 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 ofF
are isomorphic to the limit overF.obj A
for all Galois objectsA
. This is obtained as the composition (slighty 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 ofendEquivSectionsFibers
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 objectA
.
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
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
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
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
Any endomorphism of a fiber functor is a unit.
Any endomorphism of a fiber functor is an isomorphism.
Equations
- ⋯ = ⋯
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
The Aut F
action on the fiber of a Galois object is transitive. See
pretransitive_of_isConnected
for the same result for connected objects.
The Aut F
action on the fiber of a connected object is transitive.
Equations
- ⋯ = ⋯