Documentation

Mathlib.CategoryTheory.Subobject.Lattice

The lattice of subobjects #

We provide the SemilatticeInf with OrderTop (subobject X) instance when [HasPullback C], and the SemilatticeSup (Subobject X) instance when [HasImages C] [HasBinaryCoproducts C].

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  • CategoryTheory.MonoOver.instInhabited = { default := }

The morphism to the top object in MonoOver X.

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    map f sends ⊤ : MonoOver X to ⟨X, f⟩ : MonoOver Y.

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      The pullback of the top object in MonoOver Y is (isomorphic to) the top object in MonoOver X.

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        There is a morphism from ⊤ : MonoOver A to the pullback of a monomorphism along itself; as the category is thin this is an isomorphism.

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          The pullback of a monomorphism along itself is isomorphic to the top object.

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            The (unique) morphism from ⊥ : MonoOver X to any other f : MonoOver X.

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              map f sends ⊥ : MonoOver X to ⊥ : MonoOver Y.

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                The object underlying ⊥ : Subobject B is (up to isomorphism) the zero object.

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                • CategoryTheory.MonoOver.botCoeIsoZero = CategoryTheory.Limits.initialIsInitial.uniqueUpToIso CategoryTheory.Limits.HasZeroObject.zeroIsInitial
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                  When [HasPullbacks C], MonoOver A has "intersections", functorial in both arguments.

                  As MonoOver A is only a preorder, this doesn't satisfy the axioms of SemilatticeInf, but we reuse all the names from SemilatticeInf because they will be used to construct SemilatticeInf (subobject A) shortly.

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                    A morphism from the "infimum" of two objects in MonoOver A to the first object.

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                      A morphism from the "infimum" of two objects in MonoOver A to the second object.

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                        def CategoryTheory.MonoOver.leInf {C : Type u₁} [CategoryTheory.Category.{v₁, u₁} C] [CategoryTheory.Limits.HasPullbacks C] {A : C} (f : CategoryTheory.MonoOver A) (g : CategoryTheory.MonoOver A) (h : CategoryTheory.MonoOver A) :
                        (h f)(h g)(h (CategoryTheory.MonoOver.inf.obj f).obj g)

                        A morphism version of the le_inf axiom.

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                          When [HasImages C] [HasBinaryCoproducts C], MonoOver A has a sup construction, which is functorial in both arguments, and which on Subobject A will induce a SemilatticeSup.

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                            A morphism version of le_sup_left.

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                              A morphism version of le_sup_right.

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                                A morphism version of sup_le.

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                                  • CategoryTheory.Subobject.instInhabited = { default := }
                                  theorem CategoryTheory.Subobject.top_factors {C : Type u₁} [CategoryTheory.Category.{v₁, u₁} C] {A : C} {B : C} (f : A B) :
                                  .Factors f

                                  The object underlying ⊥ : Subobject B is (up to isomorphism) the initial object.

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                                    The object underlying ⊥ : Subobject B is (up to isomorphism) the zero object.

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                                    • CategoryTheory.Subobject.botCoeIsoZero = CategoryTheory.Subobject.botCoeIsoInitial ≪≫ CategoryTheory.Limits.initialIsInitial.uniqueUpToIso CategoryTheory.Limits.HasZeroObject.zeroIsInitial
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                                      Sending X : C to Subobject X is a contravariant functor Cᵒᵖ ⥤ Type.

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                                        The functorial infimum on MonoOver A descends to an infimum on Subobject A.

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                                          theorem CategoryTheory.Subobject.le_inf {C : Type u₁} [CategoryTheory.Category.{v₁, u₁} C] [CategoryTheory.Limits.HasPullbacks C] {A : C} (h : CategoryTheory.Subobject A) (f : CategoryTheory.Subobject A) (g : CategoryTheory.Subobject A) :
                                          h fh gh (CategoryTheory.Subobject.inf.obj f).obj g
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                                          theorem CategoryTheory.Subobject.inf_factors {C : Type u₁} [CategoryTheory.Category.{v₁, u₁} C] [CategoryTheory.Limits.HasPullbacks C] {A : C} {B : C} {X : CategoryTheory.Subobject B} {Y : CategoryTheory.Subobject B} (f : A B) :
                                          (X Y).Factors f X.Factors f Y.Factors f
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                                          theorem CategoryTheory.Subobject.finset_inf_factors {C : Type u₁} [CategoryTheory.Category.{v₁, u₁} C] [CategoryTheory.Limits.HasPullbacks C] {I : Type u_1} {A : C} {B : C} {s : Finset I} {P : ICategoryTheory.Subobject B} (f : A B) :
                                          (s.inf P).Factors f is, (P i).Factors f
                                          theorem CategoryTheory.Subobject.finset_inf_arrow_factors {C : Type u₁} [CategoryTheory.Category.{v₁, u₁} C] [CategoryTheory.Limits.HasPullbacks C] {I : Type u_1} {B : C} (s : Finset I) (P : ICategoryTheory.Subobject B) (i : I) (m : i s) :
                                          (P i).Factors (s.inf P).arrow

                                          The functorial supremum on MonoOver A descends to a supremum on Subobject A.

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                                            The "wide cospan" diagram, with a small indexing type, constructed from a set of subobjects. (This is just the diagram of all the subobjects pasted together, but using WellPowered C to make the diagram small.)

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                                              Auxiliary construction of a cone for le_inf.

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                                                The universal morphism out of the coproduct of a set of subobjects, after using [WellPowered C] to reindex by a small type.

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                                                  theorem CategoryTheory.Subobject.symm_apply_mem_iff_mem_image {α : Type u_1} {β : Type u_2} (e : α β) (s : Set α) (x : β) :
                                                  e.symm x s x e '' s

                                                  The subobject lattice of a subobject Y is order isomorphic to the interval Set.Iic Y.

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