Definition and basic properties of Galois categories #
We define the notion of a Galois category and a fiber functor as in SGA1, following the definitions in Lenstras notes (see below for a reference).
Main definitions #
PreGaloisCategory
: defining properties of Galois categories not involving a fiber functorFiberFunctor
: a fiber functor from aPreGaloisCategory
toFintypeCat
GaloisCategory
: aPreGaloisCategory
that admits aFiberFunctor
IsConnected
: an object of a category is connected if it is not initial and does not have non-trivial subobjects
Implementation details #
We mostly follow Def 3.1 in Lenstras notes. In axiom (G3) we omit the factorisation of morphisms in epimorphisms and monomorphisms as this is not needed for the proof of the fundamental theorem on Galois categories (and then follows from it).
References #
- [lenstraGSchemes]: H. W. Lenstra. Galois theory for schemes.
A category C
is a PreGalois category if it satisfies all properties
of a Galois category in the sense of SGA1 that do not involve a fiber functor.
A Galois category should furthermore admit a fiber functor.
The only difference between [PreGaloisCategory C] (F : C ⥤ FintypeCat) [FiberFunctor F]
and
[GaloisCategory C]
is that the former fixes one fiber functor F
.
Definition of a (Pre)Galois category. Lenstra, Def 3.1, (G1)-(G3)
- hasTerminal : CategoryTheory.Limits.HasTerminal C
C
has a terminal object (G1). - hasPullbacks : CategoryTheory.Limits.HasPullbacks C
C
has pullbacks (G1). - hasFiniteCoproducts : CategoryTheory.Limits.HasFiniteCoproducts C
C
has finite coproducts (G2). - hasQuotientsByFiniteGroups : ∀ (G : Type u₂) [inst : Group G] [inst_1 : Finite G], CategoryTheory.Limits.HasColimitsOfShape (CategoryTheory.SingleObj G) C
C
has quotients by finite groups (G2). - monoInducesIsoOnDirectSummand : ∀ {X Y : C} (i : X ⟶ Y) [inst : CategoryTheory.Mono i], ∃ (Z : C) (u : Z ⟶ Y), Nonempty (CategoryTheory.Limits.IsColimit (CategoryTheory.Limits.BinaryCofan.mk i u))
Every monomorphism in
C
induces an isomorphism on a direct summand (G3).
Instances
C
has a terminal object (G1).
C
has pullbacks (G1).
C
has finite coproducts (G2).
C
has quotients by finite groups (G2).
Every monomorphism in C
induces an isomorphism on a direct summand (G3).
Definition of a fiber functor from a Galois category. Lenstra, Def 3.1, (G4)-(G6)
- preservesTerminalObjects : CategoryTheory.Limits.PreservesLimitsOfShape (CategoryTheory.Discrete PEmpty.{1}) F
F
preserves terminal objects (G4). - preservesPullbacks : CategoryTheory.Limits.PreservesLimitsOfShape CategoryTheory.Limits.WalkingCospan F
F
preserves pullbacks (G4). - preservesFiniteCoproducts : CategoryTheory.Limits.PreservesFiniteCoproducts F
F
preserves finite coproducts (G5). - preservesEpis : F.PreservesEpimorphisms
F
preserves epimorphisms (G5). - preservesQuotientsByFiniteGroups : (G : Type u₂) → [inst : Group G] → [inst_1 : Finite G] → CategoryTheory.Limits.PreservesColimitsOfShape (CategoryTheory.SingleObj G) F
F
preserves quotients by finite groups (G5). - reflectsIsos : F.ReflectsIsomorphisms
F
reflects isomorphisms (G6).
Instances
F
preserves epimorphisms (G5).
F
reflects isomorphisms (G6).
An object of a category C
is connected if it is not initial
and has no non-trivial subobjects. Lenstra, 3.12.
- notInitial : CategoryTheory.Limits.IsInitial X → False
X
is not an initial object. - noTrivialComponent : ∀ (Y : C) (i : Y ⟶ X) [inst : CategoryTheory.Mono i], (CategoryTheory.Limits.IsInitial Y → False) → CategoryTheory.IsIso i
X
has no non-trivial subobjects.
Instances
X
is not an initial object.
X
has no non-trivial subobjects.
A functor is said to preserve connectedness if whenever X : C
is connected,
also F.obj X
is connected.
- preserves : ∀ {X : C} [inst : CategoryTheory.PreGaloisCategory.IsConnected X], CategoryTheory.PreGaloisCategory.IsConnected (F.obj X)
F.obj X
is connected ifX
is connected.
Instances
F.obj X
is connected if X
is connected.
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- CategoryTheory.PreGaloisCategory.FiberFunctor.instReflectsLimitsOfShapeFintypeCatDiscretePEmpty = CategoryTheory.Limits.reflectsLimitsOfShapeOfReflectsIsomorphisms
Equations
- CategoryTheory.PreGaloisCategory.FiberFunctor.instReflectsColimitsOfShapeFintypeCatDiscretePEmpty = CategoryTheory.Limits.reflectsColimitsOfShapeOfReflectsIsomorphisms
Equations
- CategoryTheory.PreGaloisCategory.FiberFunctor.instPreservesFiniteLimitsFintypeCat = CategoryTheory.Limits.preservesFiniteLimitsOfPreservesTerminalAndPullbacks F
Fiber functors reflect monomorphisms.
Equations
- ⋯ = ⋯
Fiber functors are faithful.
Equations
- ⋯ = ⋯
The canonical action of Aut F
on the fiber of each object.
An object is initial if and only if its fiber is empty.
An object is not initial if and only if its fiber is nonempty.
An object whose fiber is inhabited is not initial.
An object that is neither initial or connected has a non-trivial subobject.
The fiber of a connected object is nonempty.
Equations
- ⋯ = ⋯
The fiber of the equalizer of f g : X ⟶ Y
is equivalent to the set of agreement of f
and g
.
Equations
- One or more equations did not get rendered due to their size.
Instances For
The fiber of the pullback is the fiber product of the fibers.
Equations
- One or more equations did not get rendered due to their size.
Instances For
The fiber of the binary product is the binary product of the fibers.
Equations
- One or more equations did not get rendered due to their size.
Instances For
The evaluation map is injective for connected objects.
The evaluation map on automorphisms is injective for connected objects.
A morphism from an object X
with non-empty fiber to a connected object A
is an
epimorphism.
An epimorphism induces a surjective map on fibers.
A mono between objects with equally sized fibers is an iso.
Along a mono that is not an iso, the cardinality of the fiber strictly increases.
The cardinality of the fiber of a not-initial object is non-zero.
The cardinality of the fiber of a coproduct is the sum of the cardinalities of the fibers.
The cardinality of the fiber is preserved under isomorphisms.
The cardinality of morphisms A ⟶ X
is smaller than the cardinality of
the fiber of the target if the source is connected.
If A
is connected, the cardinality of Aut A
is smaller than the cardinality of the
fiber of A
.
A PreGaloisCategory
is a GaloisCategory
if it admits a fiber functor.
- hasTerminal : CategoryTheory.Limits.HasTerminal C
- hasPullbacks : CategoryTheory.Limits.HasPullbacks C
- hasFiniteCoproducts : CategoryTheory.Limits.HasFiniteCoproducts C
- hasQuotientsByFiniteGroups : ∀ (G : Type u₂) [inst : Group G] [inst_1 : Finite G], CategoryTheory.Limits.HasColimitsOfShape (CategoryTheory.SingleObj G) C
- monoInducesIsoOnDirectSummand : ∀ {X Y : C} (i : X ⟶ Y) [inst : CategoryTheory.Mono i], ∃ (Z : C) (u : Z ⟶ Y), Nonempty (CategoryTheory.Limits.IsColimit (CategoryTheory.Limits.BinaryCofan.mk i u))
- hasFiberFunctor : ∃ (F : CategoryTheory.Functor C FintypeCat), Nonempty (CategoryTheory.PreGaloisCategory.FiberFunctor F)
Instances
Arbitrarily choose a fiber functor for a Galois category using choice.
Instances For
The arbitrarily chosen fiber functor GaloisCategory.getFiberFunctor
is a fiber functor.
In a GaloisCategory
the set of morphisms out of a connected object is finite.
Equations
- ⋯ = ⋯
In a GaloisCategory
the set of automorphism of a connected object is finite.
Equations
- ⋯ = ⋯
Coproduct inclusions are monic in Galois categories.
Equations
- ⋯ = ⋯