In mathematics, specifically in the field known as category theory, a monoidal category where the monoidal ("tensor") product is the categorical product is called a cartesian monoidal category. Any category with finite products (a "finite product category") can be thought of as a cartesian monoidal category. In any cartesian monoidal category, the terminal object is the monoidal unit. Dually, a monoidal finite coproduct category with the monoidal structure given by the coproduct and unit the initial object is called a cocartesian monoidal category, and any finite coproduct category can be thought of as a cocartesian monoidal category.
Cartesian categories with an internal Hom functor that is an adjoint functor to the product are called Cartesian closed categories.
Cartesian monoidal categories have a number of special and important properties, such as the existence of diagonal maps ÃÂ<sub>x</sub> : x â x â x and augmentations e<sub>x</sub> : x â I for any object x. In applications to computer science we can think of àas "duplicating data" and e as "deleting data". These maps make any object into a comonoid. In fact, any object in a cartesian monoidal category becomes a comonoid in a unique way.
Cartesian monoidal categories:
Cocartesian monoidal categories:
In each of these categories of modules equipped with a cocartesian monoidal structure, finite products and coproducts coincide (in the sense that the product and coproduct of finitely many objects are isomorphic). Or more formally, if f : X<sub>1</sub> â ... â X<sub>n</sub> â X<sub>1</sub> à... àX<sub>n</sub> is the "canonical" map from the n-ary coproduct of objects X<sub>j</sub> to their product, for a natural number n, in the event that the map f is an isomorphism, we say that a biproduct for the objects X<sub>j</sub> is an object isomorphic to and together with maps i<sub>j</sub> : X<sub>j</sub> â X and p<sub>j</sub> : X â X<sub>j</sub> such that the pair (X, {i<sub>j</sub>}) is a coproduct diagram for the objects X<sub>j</sub> and the pair (X, {p<sub>j</sub>}) is a product diagram for the objects X<sub>j</sub> , and where p<sub>j</sub> â i<sub>j</sub> = id<sub>X<sub>j</sub></sub>. If, in addition, the category in question has a zero object, so that for any objects A and B there is a unique map 0<sub>A,B</sub> : A â 0 â B, it often follows that p<sub>k</sub> â i<sub>j</sub> = : δ<sub>ij</sub>, the Kronecker delta, where we interpret 0 and 1 as the 0 maps and identity maps of the objects X<sub>j</sub> and X<sub>k</sub>, respectively. See pre-additive category for more.