Pseudo-tensor category

In mathematics, specifically category theory, a pseudo-tensor category is a generalization of a symmetric monoidal category (also known as a tensor category) introduced by A. Beilinson and V. Drinfeld in their book "Chiral algebras”.

The notion can also be defined as a colored operad or multicategory. In particular, a pseudo-tensor category with a single object is the same as an operad.

Definition

A pseudo-tensor category C consists of the following data^[1]

A class of objects,
For each finite set $I$ , each finite set of objects $X_{i},i\in I$ parametrized by $I$ and another object $Y$ , the set
$P_{I}(\{X_{i}\},Y),$
For each surjective map $J\to I$ between finite sets, finite sets of objects $\{Y_{i}\}_{i\in I},\{X_{j}\}_{j\in J}$ and an object Z, the map
$\circ :P_{I}(\{Y_{i}\},Z)\times \prod _{i\in I}P_{\pi ^{-1}(i)}(\{X_{j}\},Y_{i})\to P_{J}(\{X_{j}\},Z),$
For each object $X$ , the element $\operatorname {id} _{X}$ in $P_{*}(\{X\},X)$ where * is a set with a single element,

subject to the associativity and the unitality axioms

for surjective maps $K\to J$ and $J\to I$ , $\varphi \circ (\psi _{i}\circ \chi _{j})=(\varphi \circ \psi _{i})\circ \chi _{j}$ ,
$\operatorname {id} _{Y}\circ \varphi =\varphi \circ \operatorname {id} _{X_{i}}=\varphi$ .

Let C be a pseudo-tensor category. For given objects $X,Y$ , let $\operatorname {Hom} (X,Y)=P_{*}(\{X\},Y)$ . Then the class of objects in $C$ together with Hom, $\circ$ and the identities form a category. Thus, a pseudo-tensor category can be thought of as a category together with extra data. In particular, a category is the same thing as a pseudo-tensor category with $P_{I}=\emptyset ,\#I>1$ .^[2]

On the other extreme, a pseudo-tensor category with a single object is the same as an operad.^[3] Indeed, a category with a single object is a monoid (unital semigroup) and thus a pseudo-tensor category with a single is like a monoid but with various n-ary operators. A finite set $\{X_{i}\}_{i\in I}$ in the definition of a pseudo-tensor is an unordered finite set. This amounts to the invariance under a symmetric group in the definition of an operad.

Finally, let C be a symmetric monoidal category. Then let

P_{I}(\{X_{i}\},Y)=\operatorname {Hom} (\otimes _{i\in I}X_{i},Y),

which is well-defined since C is symmetric. The symmetric-monoidal structure include coherent isomorphisms

\otimes _{j\in J}X_{j}{\overset {\sim }{\to }}\otimes _{i\in I}(\otimes _{j\in \pi ^{-1}(i)}X_{j})

which gives $\circ$ in the definition of a pseudo-tensor category. Conversely, a pseudo-tensor category with such $\otimes _{i\in I}X_{i}$ and coherent isomorphisms defines a symmetric monoidal category. In this way, a pseudo-tensor category generalizes a symmetric monoidal category.^[4]

In the definition, we can drop the symmetry requirement; namely, instead of a finite set of objects, we can use a finite sequence of objects. In this case, we get the notion of a multicategory. In other words, a pseudo-tensor category is (essentially) a symmetric multicategory.

Linear case

Like an enriched category, a pseudo-tensor category can also be defined over a symmetric monoidal category V; namely, we require $P_{I}$ as well as $\circ$ take values in V instead of the category of sets in the definition. A particularly important case is when V is the category of vector spaces; i.e., the images of $P_{I}$ are sets of multilinear maps and if tensor product is available,

P_{I}(\{X_{i}\},Y)=\operatorname {Hom} (\otimes _{i\in I}X_{i},Y).

References

^ Beilinson & Drinfeld, 1.1.1.
^ Beilinson & Drinfeld, 1.1.2.
^ Beilinson & Drinfeld, 1.1.4.
^ Beilinson & Drinfeld, 1.1.3.

Ch. 1 of A. Beilinson and V. Drinfeld, "Chiral algebras," [1]
§ 1.4. of Kontsevich, Maxim; Soibelman, Yan (2000). "Deformations of algebras over operads and Deligne's conjecture". Conférence Moshé Flato 1999: Quantization, Deformations, and Symmetries I. pp. 255–307. arXiv:math/0001151. ISBN 9780792365402.

Definition

Linear case

References

Further reading