End (category theory)

End (category theory)
Not to be confused with the use of End to represent (categories of) endomorphisms.

In category theory, an end of a functor S:\mathbf{C}^{\mathrm{op}}\times\mathbf{C}\to \mathbf{X} is a universal dinatural transformation from an object e of X to S.

More explicitly, this is a pair (e,ω), where e is an object of X and

\omega:e\ddot\to S

is a dinatural transformation from the constant functor whose value is e on every object and 1e on every morphism, such that for every dinatural transformation

\beta : x\ddot\to S

there exists a unique morphism

h:x\to e

of X with

\beta_a=\omega_a\circ h

for every object a of C.

By abuse of language the object e is often called the end of the functor S (forgetting ω) and is written

e=\int_c^{} S(c,c)\text{ or just }\int_\mathbf{C}^{} S.

If X is complete, the end can be described as the equalizer in the diagram

\int_c S(c, c) \to \prod_{c \in C} S(c, c) \rightrightarrows \prod_{c \to c'} S(c, c'),

where the first morphism is induced by S(c, c) \to S(c, c') and the second morphism is induced by S(c', c') \to S(c, c').

Coend

The definition of the coend of a functor S:\mathbf{C}^{\mathrm{op}}\times\mathbf{C}\to\mathbf{X} is the dual of the definition of an end.

Thus, a coend of S consists of a pair (d,ζ), where d is an object of X and

\zeta:S\ddot\to d

is a dinatural transformation, such that for every dinatural transformation

\gamma:S\ddot\to x

there exists a unique morphism

g:d\to x

of X with

\gamma_a=g\circ\zeta_a

for every object a of C.

The coend d of the functor S is written

d=\int_{}^c S(c,c)\text{ or }\int_{}^\mathbf{C} S.

Dually, if X is cocomplete, then the coend can be described as the coequalizer in the diagram

\int^c S(c, c) \leftarrow \coprod_{c \in C} S(c, c) \leftleftarrows \coprod_{c \to c'} S(c', c).

Examples

Suppose we have functors F, G : \mathbf{C} \to \mathbf{X} then Hom_{\mathbf{X}}(F(-), G(-)) : \mathbf{C}^{op} \times \mathbf{C} \to \mathbf{Set}. In this case, the category of sets is complete, so we need only form the equalizer and in this case

\int_c Hom_{\mathbf{X}}(F(c), G(c)) = Nat(F, G)

the natural transformations from F to G. Intuitively, a natural transformation from F to G is a morphism from F(c) to G(c) for every c in the category with compatibility conditions. Looking at the equalizer diagram defining the end makes the equivalence clear.

Let T be a simplicial set. That is, T is a functor \Delta^{\mathrm{op}} \to \mathbf{Set} The Discrete topology gives a functor \mathbf{Set} \to \mathbf{Top}, where \mathbf{Top} is the category of topological spaces. Moreover, there is a map \gamma:\Delta \to \mathbf{Top} which sends the object [n] of Δ to the standard n simplex inside \mathbb{R}^{n+1}. Finally there is a functor \mathbf{Top} \times \mathbf{Top} \to \mathbf{Top} which takes the product of two topological spaces. Define S to be the composition of this product functor with T \times \gamma. The coend of S is the geometric realization of T.

References


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