Integral transform

In category theory, a coequalizer (or coequaliser) is a generalization of a quotient by an equivalence relation to objects in an arbitrary category. It is the categorical construction dual to the equalizer (hence the name).

Definition

A coequalizer is a colimit of the diagram consisting of two objects X and Y and two parallel morphisms f, g : X → Y.

More explicitly, a coequalizer can be defined as an object Q together with a morphism q : Y → Q such that q ∘ f = q ∘ g. Moreover, the pair (Q, q) must be universal in the sense that given any other such pair (Q′, q′) there exists a unique morphism u : Q → Q′ for which the following diagram commutes:

As with all universal constructions, a coequalizer, if it exists, is unique up to a unique isomorphism (this is why, by abuse of language, one sometimes speaks of "the" coequalizer of two parallel arrows).

It can be shown that a coequalizer q is an epimorphism in any category.

Examples

• In the category of sets, the coequalizer of two functions f, g : X → Y is the quotient of Y by the smallest equivalence relation ${\displaystyle ~\sim }$ such that for every ${\displaystyle x\in X}$, we have ${\displaystyle f(x)\sim g(x)}$.^[1] In particular, if R is an equivalence relation on a set Y, and r₁, r₂ are the natural projections (R ⊂ Y × Y) → Y then the coequalizer of r₁ and r₂ is the quotient set Y/R.

• The coequalizer in the category of groups is very similar. Here if f, g : X → Y are group homomorphisms, their coequalizer is the quotient of Y by the normal closure of the set

${\displaystyle S=\{f(x)g(x)^{-1}\ |\ x\in X\}}$

• For abelian groups the coequalizer is particularly simple. It is just the factor group Y / im(f – g). (This is the cokernel of the morphism f – g; see the next section).

• In the category of topological spaces, the circle object ${\displaystyle S^{1}}$ can be viewed as the coequalizer of the two inclusion maps from the standard 0-simplex to the standard 1-simplex.

• Coequalisers can be large: There are exactly two functors from the category 1 having one object and one identity arrow, to the category 2 with two objects and exactly one non-identity arrow going between them. The coequaliser of these two functors is the monoid of natural numbers under addition, considered as a one-object category. In particular, this shows that while every coequalising arrow is epic, it is not necessarily surjective.

Properties

• In a topos, every epimorphism is the coequalizer of its kernel pair.
• Every coequalizer is an epimorphism.

Special cases

In categories with zero morphisms, one can define a cokernel of a morphism f as the coequalizer of f and the parallel zero morphism.

In preadditive categories it makes sense to add and subtract morphisms (the hom-sets actually form abelian groups). In such categories, one can define the coequalizer of two morphisms f and g as the cokernel of their difference:

coeq(f, g) = coker(g – f).

A stronger notion is that of an absolute coequalizer, this is a coequalizer that is preserved under all functors. Formally, an absolute coequalizer of a pair ${\displaystyle f,g:X\to Y}$ in a category C is a coequalizer as defined above but with the added property that given any functor ${\displaystyle F:C\to D}$ F(Q) together with F(q) is the coequalizer of F(f) and F(g) in the category D. Split coequalizers are examples of absolute coequalizers.

See also

• equalizer (mathematics)
• coproduct
• pushout

Notes

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References

• Saunders Mac Lane: Categories for the Working Mathematician, Second Edition, 1998.
• Coequalizers - page 65
• Absolute coequalizers - page 149

External links

• Interactive Web page which generates examples of coequalizers in the category of finite sets. Written by Jocelyn Paine.