HepLean Documentation

Mathlib.CategoryTheory.Comma.Over

Over and under categories #

Over (and under) categories are special cases of comma categories.

Tags #

Comma, Slice, Coslice, Over, Under

def CategoryTheory.Over {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] (X : T) :
Type (max u₁ v₁)

The over category has as objects arrows in T with codomain X and as morphisms commutative triangles.

See https://stacks.math.columbia.edu/tag/001G.

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    theorem CategoryTheory.Over.OverMorphism.ext {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {U V : CategoryTheory.Over X} {f g : U V} (h : f.left = g.left) :
    f = g
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    @[simp]

    To give an object in the over category, it suffices to give a morphism with codomain X.

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      We can set up a coercion from arrows with codomain X to over X. This most likely should not be a global instance, but it is sometimes useful.

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      • CategoryTheory.Over.coeFromHom = { coe := CategoryTheory.Over.mk }
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        def CategoryTheory.Over.homMk {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {U V : CategoryTheory.Over X} (f : U.left V.left) (w : CategoryTheory.CategoryStruct.comp f V.hom = U.hom := by aesop_cat) :
        U V

        To give a morphism in the over category, it suffices to give an arrow fitting in a commutative triangle.

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          theorem CategoryTheory.Over.homMk_left {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {U V : CategoryTheory.Over X} (f : U.left V.left) (w : CategoryTheory.CategoryStruct.comp f V.hom = U.hom := by aesop_cat) :
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          theorem CategoryTheory.Over.homMk_right_down_down {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {U V : CategoryTheory.Over X} (f : U.left V.left) (w : CategoryTheory.CategoryStruct.comp f V.hom = U.hom := by aesop_cat) :
          =
          def CategoryTheory.Over.isoMk {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {f g : CategoryTheory.Over X} (hl : f.left g.left) (hw : CategoryTheory.CategoryStruct.comp hl.hom g.hom = f.hom := by aesop_cat) :
          f g

          Construct an isomorphism in the over category given isomorphisms of the objects whose forward direction gives a commutative triangle.

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            theorem CategoryTheory.Over.isoMk_hom_right_down_down {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {f g : CategoryTheory.Over X} (hl : f.left g.left) (hw : CategoryTheory.CategoryStruct.comp hl.hom g.hom = f.hom := by aesop_cat) :
            =
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            theorem CategoryTheory.Over.isoMk_hom_left {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {f g : CategoryTheory.Over X} (hl : f.left g.left) (hw : CategoryTheory.CategoryStruct.comp hl.hom g.hom = f.hom := by aesop_cat) :
            (CategoryTheory.Over.isoMk hl hw).hom.left = hl.hom
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            theorem CategoryTheory.Over.isoMk_inv_right_down_down {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {f g : CategoryTheory.Over X} (hl : f.left g.left) (hw : CategoryTheory.CategoryStruct.comp hl.hom g.hom = f.hom := by aesop_cat) :
            =
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            theorem CategoryTheory.Over.isoMk_inv_left {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {f g : CategoryTheory.Over X} (hl : f.left g.left) (hw : CategoryTheory.CategoryStruct.comp hl.hom g.hom = f.hom := by aesop_cat) :
            (CategoryTheory.Over.isoMk hl hw).inv.left = hl.inv

            The natural cocone over the forgetful functor Over X ⥤ T with cocone point X.

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              theorem CategoryTheory.Over.map_obj_left {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X Y : T} {f : X Y} {U : CategoryTheory.Over X} :
              ((CategoryTheory.Over.map f).obj U).left = U.left
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              theorem CategoryTheory.Over.map_map_left {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X Y : T} {f : X Y} {U V : CategoryTheory.Over X} {g : U V} :
              ((CategoryTheory.Over.map f).map g).left = g.left

              This section proves various equalities between functors that demonstrate, for instance, that over categories assemble into a functor mapFunctor : T ⥤ Cat.

              These equalities between functors are then converted to natural isomorphisms using eqToIso. Such natural isomorphisms could be obtained directly using Iso.refl but this method will have better computational properties, when used, for instance, in developing the theory of Beck-Chevalley transformations.

              Mapping by f and then forgetting is the same as forgetting.

              Mapping by the composite morphism f ≫ g is the same as mapping by f then by g.

              If f = g, then map f is naturally isomorphic to map g.

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                theorem CategoryTheory.Over.mapCongr_inv_app {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X Y : T} (f g : X Y) (h : f = g) (X✝ : CategoryTheory.Over X) :
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                theorem CategoryTheory.Over.mapCongr_hom_app {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X Y : T} (f g : X Y) (h : f = g) (X✝ : CategoryTheory.Over X) :

                The functor defined by the over categories.

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                  The identity over X is terminal.

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                  • CategoryTheory.Over.mkIdTerminal = CategoryTheory.CostructuredArrow.mkIdTerminal
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                    If k.left is an epimorphism, then k is an epimorphism. In other words, Over.forget X reflects epimorphisms. The converse does not hold without additional assumptions on the underlying category, see CategoryTheory.Over.epi_left_of_epi.

                    If k.left is a monomorphism, then k is a monomorphism. In other words, Over.forget X reflects monomorphisms. The converse of CategoryTheory.Over.mono_left_of_mono.

                    This lemma is not an instance, to avoid loops in type class inference.

                    If k is a monomorphism, then k.left is a monomorphism. In other words, Over.forget X preserves monomorphisms. The converse of CategoryTheory.Over.mono_of_mono_left.

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                    Given f : Y ⟶ X, this is the obvious functor from (T/X)/f to T/Y

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                      theorem CategoryTheory.Over.iteratedSliceForward_map {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} (f : CategoryTheory.Over X) {X✝ Y✝ : CategoryTheory.Over f} (κ : X✝ Y✝) :
                      f.iteratedSliceForward.map κ = CategoryTheory.Over.homMk κ.left.left
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                      theorem CategoryTheory.Over.iteratedSliceForward_obj {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} (f : CategoryTheory.Over X) (α : CategoryTheory.Over f) :
                      f.iteratedSliceForward.obj α = CategoryTheory.Over.mk α.hom.left

                      Given f : Y ⟶ X, this is the obvious functor from T/Y to (T/X)/f

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                        theorem CategoryTheory.Over.iteratedSliceBackward_map {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} (f : CategoryTheory.Over X) {X✝ Y✝ : CategoryTheory.Over f.left} (α : X✝ Y✝) :
                        f.iteratedSliceBackward.map α = CategoryTheory.Over.homMk (CategoryTheory.Over.homMk α.left )

                        Given f : Y ⟶ X, we have an equivalence between (T/X)/f and T/Y

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                          theorem CategoryTheory.Over.iteratedSliceEquiv_counitIso {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} (f : CategoryTheory.Over X) :
                          f.iteratedSliceEquiv.counitIso = CategoryTheory.NatIso.ofComponents (fun (g : CategoryTheory.Over f.left) => CategoryTheory.Over.isoMk (CategoryTheory.Iso.refl ((f.iteratedSliceBackward.comp f.iteratedSliceForward).obj g).left) )
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                          theorem CategoryTheory.Over.iteratedSliceEquiv_functor {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} (f : CategoryTheory.Over X) :
                          f.iteratedSliceEquiv.functor = f.iteratedSliceForward
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                          theorem CategoryTheory.Over.iteratedSliceEquiv_inverse {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} (f : CategoryTheory.Over X) :
                          f.iteratedSliceEquiv.inverse = f.iteratedSliceBackward

                          A functor F : T ⥤ D induces a functor Over X ⥤ Over (F.obj X) in the obvious way.

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                            A natural transformation F ⟶ G induces a natural transformation on Over X up to Under.map.

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                              If F and G are naturally isomorphic, then Over.post F and Over.post G are also naturally isomorphic up to Over.map

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                                theorem CategoryTheory.Over.postCongr_inv_app_left {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {D : Type u₂} [CategoryTheory.Category.{v₂, u₂} D] {X : T} {F G : CategoryTheory.Functor T D} (e : F G) (X✝ : CategoryTheory.Over X) :
                                ((CategoryTheory.Over.postCongr e).inv.app X✝).left = e.inv.app X✝.left
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                                theorem CategoryTheory.Over.postCongr_hom_app_left {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {D : Type u₂} [CategoryTheory.Category.{v₂, u₂} D] {X : T} {F G : CategoryTheory.Functor T D} (e : F G) (X✝ : CategoryTheory.Over X) :
                                ((CategoryTheory.Over.postCongr e).hom.app X✝).left = e.hom.app X✝.left

                                An equivalence of categories induces an equivalence on over categories.

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                                  Reinterpreting an F-costructured arrow F.obj d ⟶ X as an arrow over X induces a functor CostructuredArrow F X ⥤ Over X.

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                                    An equivalence F induces an equivalence CostructuredArrow F X ≌ Over X.

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                                    def CategoryTheory.Under {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] (X : T) :
                                    Type (max u₁ v₁)

                                    The under category has as objects arrows with domain X and as morphisms commutative triangles.

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                                      theorem CategoryTheory.Under.UnderMorphism.ext {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {U V : CategoryTheory.Under X} {f g : U V} (h : f.right = g.right) :
                                      f = g
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                                      To give an object in the under category, it suffices to give an arrow with domain X.

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                                        def CategoryTheory.Under.homMk {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {U V : CategoryTheory.Under X} (f : U.right V.right) (w : CategoryTheory.CategoryStruct.comp U.hom f = V.hom := by aesop_cat) :
                                        U V

                                        To give a morphism in the under category, it suffices to give a morphism fitting in a commutative triangle.

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                                          theorem CategoryTheory.Under.homMk_right {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {U V : CategoryTheory.Under X} (f : U.right V.right) (w : CategoryTheory.CategoryStruct.comp U.hom f = V.hom := by aesop_cat) :
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                                          theorem CategoryTheory.Under.homMk_left_down_down {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {U V : CategoryTheory.Under X} (f : U.right V.right) (w : CategoryTheory.CategoryStruct.comp U.hom f = V.hom := by aesop_cat) :
                                          =
                                          def CategoryTheory.Under.isoMk {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {f g : CategoryTheory.Under X} (hr : f.right g.right) (hw : CategoryTheory.CategoryStruct.comp f.hom hr.hom = g.hom := by aesop_cat) :
                                          f g

                                          Construct an isomorphism in the over category given isomorphisms of the objects whose forward direction gives a commutative triangle.

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                                            theorem CategoryTheory.Under.isoMk_hom_right {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {f g : CategoryTheory.Under X} (hr : f.right g.right) (hw : CategoryTheory.CategoryStruct.comp f.hom hr.hom = g.hom) :
                                            (CategoryTheory.Under.isoMk hr hw).hom.right = hr.hom
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                                            theorem CategoryTheory.Under.isoMk_inv_right {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X : T} {f g : CategoryTheory.Under X} (hr : f.right g.right) (hw : CategoryTheory.CategoryStruct.comp f.hom hr.hom = g.hom) :
                                            (CategoryTheory.Under.isoMk hr hw).inv.right = hr.inv

                                            The natural cone over the forgetful functor Under X ⥤ T with cone point X.

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                                              theorem CategoryTheory.Under.map_obj_right {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X Y : T} {f : X Y} {U : CategoryTheory.Under Y} :
                                              ((CategoryTheory.Under.map f).obj U).right = U.right
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                                              theorem CategoryTheory.Under.map_map_right {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {X Y : T} {f : X Y} {U V : CategoryTheory.Under Y} {g : U V} :
                                              ((CategoryTheory.Under.map f).map g).right = g.right

                                              This section proves various equalities between functors that demonstrate, for instance, that under categories assemble into a functor mapFunctor : Tᵒᵖ ⥤ Cat.

                                              Mapping by f and then forgetting is the same as forgetting.

                                              Mapping by the composite morphism f ≫ g is the same as mapping by f then by g.

                                              If f = g, then map f is naturally isomorphic to map g.

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                                                The functor defined by the under categories.

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                                                  The identity under X is initial.

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                                                  • CategoryTheory.Under.mkIdInitial = CategoryTheory.StructuredArrow.mkIdInitial
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                                                    If k.right is a monomorphism, then k is a monomorphism. In other words, Under.forget X reflects epimorphisms. The converse does not hold without additional assumptions on the underlying category, see CategoryTheory.Under.mono_right_of_mono.

                                                    If k.right is an epimorphism, then k is an epimorphism. In other words, Under.forget X reflects epimorphisms. The converse of CategoryTheory.Under.epi_right_of_epi.

                                                    This lemma is not an instance, to avoid loops in type class inference.

                                                    If k is an epimorphism, then k.right is an epimorphism. In other words, Under.forget X preserves epimorphisms. The converse of CategoryTheory.under.epi_of_epi_right.

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                                                    A functor F : T ⥤ D induces a functor Under X ⥤ Under (F.obj X) in the obvious way.

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                                                      A natural transformation F ⟶ G induces a natural transformation on Under X up to Under.map.

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                                                        If F and G are naturally isomorphic, then Under.post F and Under.post G are also naturally isomorphic up to Under.map

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                                                          theorem CategoryTheory.Under.postCongr_hom_app_right {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {D : Type u₂} [CategoryTheory.Category.{v₂, u₂} D] {X : T} {F G : CategoryTheory.Functor T D} (e : F G) (X✝ : CategoryTheory.Under X) :
                                                          ((CategoryTheory.Under.postCongr e).hom.app X✝).right = e.hom.app X✝.right
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                                                          theorem CategoryTheory.Under.postCongr_inv_app_right {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {D : Type u₂} [CategoryTheory.Category.{v₂, u₂} D] {X : T} {F G : CategoryTheory.Functor T D} (e : F G) (X✝ : CategoryTheory.Under X) :
                                                          ((CategoryTheory.Under.postCongr e).inv.app X✝).right = e.inv.app X✝.right

                                                          An equivalence of categories induces an equivalence on under categories.

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                                                            Reinterpreting an F-structured arrow X ⟶ F.obj d as an arrow under X induces a functor StructuredArrow X F ⥤ Under X.

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                                                              An equivalence F induces an equivalence StructuredArrow X F ≌ Under X.

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                                                              def CategoryTheory.Functor.toOver {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {S : Type u₂} [CategoryTheory.Category.{v₂, u₂} S] (F : CategoryTheory.Functor S T) (X : T) (f : (Y : S) → F.obj Y X) (h : ∀ {Y Z : S} (g : Y Z), CategoryTheory.CategoryStruct.comp (F.map g) (f Z) = f Y) :

                                                              Given X : T, to upgrade a functor F : S ⥤ T to a functor S ⥤ Over X, it suffices to provide maps F.obj Y ⟶ X for all Y making the obvious triangles involving all F.map g commute.

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                                                                theorem CategoryTheory.Functor.toOver_obj_left {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {S : Type u₂} [CategoryTheory.Category.{v₂, u₂} S] (F : CategoryTheory.Functor S T) (X : T) (f : (Y : S) → F.obj Y X) (h : ∀ {Y Z : S} (g : Y Z), CategoryTheory.CategoryStruct.comp (F.map g) (f Z) = f Y) (Y : S) :
                                                                ((F.toOver X f h).obj Y).left = F.obj Y
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                                                                theorem CategoryTheory.Functor.toOver_map_left {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {S : Type u₂} [CategoryTheory.Category.{v₂, u₂} S] (F : CategoryTheory.Functor S T) (X : T) (f : (Y : S) → F.obj Y X) (h : ∀ {Y Z : S} (g : Y Z), CategoryTheory.CategoryStruct.comp (F.map g) (f Z) = f Y) {X✝ Y✝ : S} (g : X✝ Y✝) :
                                                                ((F.toOver X f h).map g).left = F.map g
                                                                def CategoryTheory.Functor.toOverCompForget {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {S : Type u₂} [CategoryTheory.Category.{v₂, u₂} S] (F : CategoryTheory.Functor S T) (X : T) (f : (Y : S) → F.obj Y X) (h : ∀ {Y Z : S} (g : Y Z), CategoryTheory.CategoryStruct.comp (F.map g) (f Z) = f Y) :
                                                                (F.toOver X f ).comp (CategoryTheory.Over.forget X) F

                                                                Upgrading a functor S ⥤ T to a functor S ⥤ Over X and composing with the forgetful functor Over X ⥤ T recovers the original functor.

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                                                                  theorem CategoryTheory.Functor.toOver_comp_forget {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {S : Type u₂} [CategoryTheory.Category.{v₂, u₂} S] (F : CategoryTheory.Functor S T) (X : T) (f : (Y : S) → F.obj Y X) (h : ∀ {Y Z : S} (g : Y Z), CategoryTheory.CategoryStruct.comp (F.map g) (f Z) = f Y) :
                                                                  (F.toOver X f ).comp (CategoryTheory.Over.forget X) = F
                                                                  def CategoryTheory.Functor.toUnder {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {S : Type u₂} [CategoryTheory.Category.{v₂, u₂} S] (F : CategoryTheory.Functor S T) (X : T) (f : (Y : S) → X F.obj Y) (h : ∀ {Y Z : S} (g : Y Z), CategoryTheory.CategoryStruct.comp (f Y) (F.map g) = f Z) :

                                                                  Given X : T, to upgrade a functor F : S ⥤ T to a functor S ⥤ Under X, it suffices to provide maps X ⟶ F.obj Y for all Y making the obvious triangles involving all F.map g commute.

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                                                                    theorem CategoryTheory.Functor.toUnder_map_right {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {S : Type u₂} [CategoryTheory.Category.{v₂, u₂} S] (F : CategoryTheory.Functor S T) (X : T) (f : (Y : S) → X F.obj Y) (h : ∀ {Y Z : S} (g : Y Z), CategoryTheory.CategoryStruct.comp (f Y) (F.map g) = f Z) {X✝ Y✝ : S} (g : X✝ Y✝) :
                                                                    ((F.toUnder X f h).map g).right = F.map g
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                                                                    theorem CategoryTheory.Functor.toUnder_obj_right {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {S : Type u₂} [CategoryTheory.Category.{v₂, u₂} S] (F : CategoryTheory.Functor S T) (X : T) (f : (Y : S) → X F.obj Y) (h : ∀ {Y Z : S} (g : Y Z), CategoryTheory.CategoryStruct.comp (f Y) (F.map g) = f Z) (Y : S) :
                                                                    ((F.toUnder X f h).obj Y).right = F.obj Y
                                                                    def CategoryTheory.Functor.toUnderCompForget {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {S : Type u₂} [CategoryTheory.Category.{v₂, u₂} S] (F : CategoryTheory.Functor S T) (X : T) (f : (Y : S) → X F.obj Y) (h : ∀ {Y Z : S} (g : Y Z), CategoryTheory.CategoryStruct.comp (f Y) (F.map g) = f Z) :
                                                                    (F.toUnder X f ).comp (CategoryTheory.Under.forget X) F

                                                                    Upgrading a functor S ⥤ T to a functor S ⥤ Under X and composing with the forgetful functor Under X ⥤ T recovers the original functor.

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                                                                      theorem CategoryTheory.Functor.toUnder_comp_forget {T : Type u₁} [CategoryTheory.Category.{v₁, u₁} T] {S : Type u₂} [CategoryTheory.Category.{v₂, u₂} S] (F : CategoryTheory.Functor S T) (X : T) (f : (Y : S) → X F.obj Y) (h : ∀ {Y Z : S} (g : Y Z), CategoryTheory.CategoryStruct.comp (f Y) (F.map g) = f Z) :
                                                                      (F.toUnder X f ).comp (CategoryTheory.Under.forget X) = F

                                                                      A functor from the structured arrow category on the projection functor for any structured arrow category.

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                                                                        Characterization of the structured arrow category on the projection functor of any structured arrow category.

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                                                                          The canonical functor from the structured arrow category on the diagonal functor T ⥤ T × T to the structured arrow category on Under.forget.

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                                                                            Characterization of the structured arrow category on the diagonal functor T ⥤ T × T.

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                                                                              A version of StructuredArrow.ofDiagEquivalence with the roles of the first and second projection swapped.

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                                                                                A functor from the costructured arrow category on the projection functor for any costructured arrow category.

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                                                                                  Characterization of the costructured arrow category on the projection functor of any costructured arrow category.

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                                                                                    The canonical functor from the costructured arrow category on the diagonal functor T ⥤ T × T to the costructured arrow category on Under.forget.

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                                                                                      Characterization of the costructured arrow category on the diagonal functor T ⥤ T × T.

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                                                                                        A version of CostructuredArrow.ofDiagEquivalence with the roles of the first and second projection swapped.

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                                                                                          The canonical functor by reversing structure arrows.

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                                                                                            The canonical functor by reversing structure arrows.

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                                                                                              Over.opToOpUnder is an equivalence of categories.

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                                                                                                The canonical functor by reversing structure arrows.

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                                                                                                  The canonical functor by reversing structure arrows.

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                                                                                                    Under.opToOpOver is an equivalence of categories.

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