HepLean Documentation

Mathlib.CategoryTheory.Limits.ConeCategory

Limits and the category of (co)cones #

This files contains results that stem from the limit API. For the definition and the category instance of Cone, please refer to CategoryTheory/Limits/Cones.lean.

Main results #

Given a cone c over F, we can interpret the legs of c as structured arrows c.pt ⟶ F.obj -.

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    If F has a limit, then the limit projections can be interpreted as structured arrows limit F ⟶ F.obj -.

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      Cone.toStructuredArrow can be expressed in terms of Functor.toStructuredArrow.

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        def CategoryTheory.Functor.toStructuredArrowIsoToStructuredArrow {J : Type u₁} [CategoryTheory.Category.{v₁, u₁} J] {K : Type u₂} [CategoryTheory.Category.{v₂, u₂} K] {C : Type u₃} [CategoryTheory.Category.{v₃, u₃} C] (G : CategoryTheory.Functor J K) (X : C) (F : CategoryTheory.Functor K C) (f : (Y : J) → X F.obj (G.obj Y)) (h : ∀ {Y Z : J} (g : Y Z), CategoryTheory.CategoryStruct.comp (f Y) (F.map (G.map g)) = f Z) :
        G.toStructuredArrow X F f { pt := X, π := { app := f, naturality := } }.toStructuredArrow.comp (CategoryTheory.StructuredArrow.pre { pt := X, π := { app := f, naturality := } }.pt G F)

        Functor.toStructuredArrow can be expressed in terms of Cone.toStructuredArrow.

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          Interpreting the legs of a cone as a structured arrow and then forgetting the arrow again does nothing.

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            Interpreting the legs of a cone as a structured arrow, interpreting this arrow as an arrow over the cone point, and finally forgetting the arrow is the same as just applying the functor the cone was over.

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              A cone c on F : J ⥤ C lifts to a cone in Over c.pt with cone point 𝟙 c.pt.

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                The limit cone for F : J ⥤ C lifts to a cocone in Under (limit F) with cone point 𝟙 (limit F). This is automatically also a limit cone.

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                  c.toUnder is a lift of c under the forgetful functor.

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                    Given a diagram of StructuredArrow X Fs, we may obtain a cone with cone point X.

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                      Given a cone c : Cone K and a map f : X ⟶ F.obj c.X, we can construct a cone of structured arrows over X with f as the cone point.

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                        Construct an object of the category (Δ ↓ F) from a cone on F. This is part of an equivalence, see Cone.equivCostructuredArrow.

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                          Construct a cone on F from an object of the category (Δ ↓ F). This is part of an equivalence, see Cone.equivCostructuredArrow.

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                            The category of cones on F is just the comma category (Δ ↓ F), where Δ is the constant functor.

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                              A cone is a limit cone iff it is terminal.

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                                Given a cocone c over F, we can interpret the legs of c as costructured arrows F.obj - ⟶ c.pt.

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                                  If F has a colimit, then the colimit inclusions can be interpreted as costructured arrows F.obj - ⟶ colimit F.

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                                    Cocone.toCostructuredArrow can be expressed in terms of Functor.toCostructuredArrow.

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                                      def CategoryTheory.Functor.toCostructuredArrowIsoToCostructuredArrow {J : Type u₁} [CategoryTheory.Category.{v₁, u₁} J] {K : Type u₂} [CategoryTheory.Category.{v₂, u₂} K] {C : Type u₃} [CategoryTheory.Category.{v₃, u₃} C] (G : CategoryTheory.Functor J K) (F : CategoryTheory.Functor K C) (X : C) (f : (Y : J) → F.obj (G.obj Y) X) (h : ∀ {Y Z : J} (g : Y Z), CategoryTheory.CategoryStruct.comp (F.map (G.map g)) (f Z) = f Y) :
                                      G.toCostructuredArrow F X f { pt := X, ι := { app := f, naturality := } }.toCostructuredArrow.comp (CategoryTheory.CostructuredArrow.pre G F { pt := X, ι := { app := f, naturality := } }.pt)

                                      Functor.toCostructuredArrow can be expressed in terms of Cocone.toCostructuredArrow.

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                                        Interpreting the legs of a cocone as a costructured arrow and then forgetting the arrow again does nothing.

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                                          Interpreting the legs of a cocone as a costructured arrow, interpreting this arrow as an arrow over the cocone point, and finally forgetting the arrow is the same as just applying the functor the cocone was over.

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                                            A cocone c on F : J ⥤ C lifts to a cocone in Over c.pt with cone point 𝟙 c.pt.

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                                              The colimit cocone for F : J ⥤ C lifts to a cocone in Over (colimit F) with cone point 𝟙 (colimit F). This is automatically also a colimit cocone.

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                                                c.toOver is a lift of c under the forgetful functor.

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                                                  Given a diagram CostructuredArrow F Xs, we may obtain a cocone with cone point X.

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                                                    Given a cocone c : Cocone K and a map f : F.obj c.X ⟶ X, we can construct a cocone of costructured arrows over X with f as the cone point.

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                                                      Construct an object of the category (F ↓ Δ) from a cocone on F. This is part of an equivalence, see Cocone.equivStructuredArrow.

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                                                        Construct a cocone on F from an object of the category (F ↓ Δ). This is part of an equivalence, see Cocone.equivStructuredArrow.

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                                                          The category of cocones on F is just the comma category (F ↓ Δ), where Δ is the constant functor.

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                                                            A cocone is a colimit cocone iff it is initial.

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