Category of representations explained

In representation theory, the category of representations of some algebraic structure has the representations of as objects and equivariant maps as morphisms between them. One of the basic thrusts of representation theory is to understand the conditions under which this category is semisimple; i.e., whether an object decomposes into simple objects (see Maschke's theorem for the case of finite groups).

The Tannakian formalism gives conditions under which a group G may be recovered from the category of representations of it together with the forgetful functor to the category of vector spaces.[1]

The Grothendieck ring of the category of finite-dimensional representations of a group G is called the representation ring of G.

Definitions

Depending on the types of the representations one wants to consider, it is typical to use slightly different definitions.

For a finite group and a field, the category of representations of over has

The category is denoted by

\operatorname{Rep}F(G)

or

\operatorname{Rep}(G)

.

For a Lie group, one typically requires the representations to be smooth or admissible. For the case of a Lie algebra, see Lie algebra representation. See also: category O.

The category of modules over the group ring

There is an isomorphism of categories between the category of representations of a group over a field (described above) and the category of modules over the group ring [{{var|G}}], denoted [{{var|G}}]-Mod.

Category-theoretic definition

G\to\operatorname{Aut}(X)

; see Automorphism group#In category theory for more. For example, a -set is equivalent to a functor from to Set, the category of sets, and a linear representation is equivalent to a functor to Vect, the category of vector spaces over a field .[2]

In this setting, the category of linear representations of over is the functor category → Vect, which has natural transformations as its morphisms.

Properties

The category of linear representations of a group has a monoidal structure given by the tensor product of representations, which is an important ingredient in Tannaka-Krein duality (see below).

Maschke's theorem states that when the characteristic of doesn't divide the order of, the category of representations of over is semisimple.

Restriction and induction

Given a group with a subgroup, there are two fundamental functors between the categories of representations of and (over a fixed field): one is a forgetful functor called the restriction functor

\begin \operatorname_H^G : \operatorname(G) &\longrightarrow \operatorname(H) \\ \pi &\longmapsto \pi|_H\endand the other, the induction functor

\operatorname_H^G : \operatorname(H) \to \operatorname(G).

When and are finite groups, they are adjoint to each other

\operatorname_G(\operatorname_H^G W, U) \cong \operatorname_H(W, \operatorname_H^G U),a theorem called Frobenius reciprocity.

The basic question is whether the decomposition into irreducible representations (simple objects of the category) behaves under restriction or induction. The question may be attacked for instance by the Mackey theory.

Tannaka-Krein duality

See main article: Tannaka–Krein duality.

Tannaka–Krein duality concerns the interaction of a compact topological group and its category of linear representations. Tannaka's theorem describes the converse passage from the category of finite-dimensional representations of a group back to the group, allowing one to recover the group from its category of representations. Krein's theorem in effect completely characterizes all categories that can arise from a group in this fashion. These concepts can be applied to representations of several different structures, see the main article for details.

External links

Notes and References

  1. Jacob. Lurie. 2004-12-14. Tannaka Duality for Geometric Stacks. math/0412266. en.
  2. Book: Mac Lane, Saunders. Categories for the Working Mathematician. 1978. Springer New York. 1441931236. Second. New York, NY. 41. 851741862.