In category theory, a branch of mathematics, a dual object is an analogue of a dual vector space from linear algebra for objects in arbitrary monoidal categories. It is only a partial generalization, based upon the categorical properties of duality for finite-dimensional vector spaces. An object admitting a dual is called a dualizable object. In this formalism, infinite-dimensional vector spaces are not dualizable, since the dual vector space V<sup>âÂÂ</sup> doesn't satisfy the axioms. Often, an object is dualizable only when it satisfies some finiteness or compactness property.
A category in which each object has a dual is called autonomous or rigid. The category of finite-dimensional vector spaces with the standard tensor product is rigid, while the category of all vector spaces is not.
Let V be a finite-dimensional vector space over some field K. The standard notion of a dual vector space V<sup>âÂÂ</sup> has the following property: for any K-vector spaces U and W there is an adjunction Hom<sub>K</sub>(U â V,W) = Hom<sub>K</sub>(U, V<sup>âÂÂ</sup> â W), and this characterizes V<sup>âÂÂ</sup> up to a unique isomorphism. This expression makes sense in any category with an appropriate replacement for the tensor product of vector spaces. For any monoidal category (C, âÂÂ) one may attempt to define a dual of an object V to be an object V<sup>âÂÂ</sup> â C with a natural isomorphism of bifunctors
For a well-behaved notion of duality, this map should be not only natural in the sense of category theory, but also respect the monoidal structure in some way. An actual definition of a dual object is thus more complicated.
In a closed monoidal category C, i.e. a monoidal category with an internal Hom functor, an alternative approach is to simulate the standard definition of a dual vector space as a space of functionals. For an object V â C define V<sup>âÂÂ</sup> to be , where 1<sub>C</sub> is the monoidal identity. In some cases, this object will be a dual object to V in a sense above, but in general it leads to a different theory.
Consider an object in a monoidal category . The object is called a left dual of if there exist two morphisms
such that the following two diagrams commute:
The object is called the right dual of . This definition is due to .
Left duals are canonically isomorphic when they exist, as are right duals. When C is braided (or symmetric), every left dual is also a right dual, and vice versa.
If we consider a monoidal category as a bicategory with one object, a dual pair is exactly an adjoint pair.
A monoidal category where every object has a left (respectively right) dual is sometimes called a left (respectively right) autonomous category. Algebraic geometers call it a left (respectively right) rigid category. A monoidal category where every object has both a left and a right dual is called an autonomous category. An autonomous category that is also symmetric is called a compact closed category.
Any endomorphism f of a dualizable object admits a trace, which is a certain endomorphism of the monoidal unit of C. This notion includes, as very special cases, the trace in linear algebra and the Euler characteristic of a chain complex.