# Finite-dimensional linear representation

*This article describes a property to be evaluated for a linear representation of a group, i.e. a homomorphism from the group to the general linear group of a vector space over a field*

This article gives a basic definition in the following area: linear representation theory

View other basic definitions in linear representation theory |View terms related to linear representation theory |View facts related to linear representation theory

## Definition

### Symbol-free definition

A linear representation of a group is termed **finite-dimensional** if its vector space is finite-dimensional as a vector space over the field.

### Definition with symbols

Let be a group and a field. A **finite-dimensional linear representation** of over is a homomorphism where is a finite-dimensional vector space over . The representation is typically expressed by the pair .

### Equivalence of representations

`Further information: equivalent linear representations`

The notion of equivalence of finite-dimensional linear representations is the same as the notion of equivalence as linear representations. Namely, given two finite-dimensional linear representations and of , an equivalence between them is a map such that for all :

In particular, when , then two representations on are equivalent if they are conjugate by an element of .

## Invariants

If is a finite-dimensional linear representation of , and has dimension , there is an isomorphism between and (i.e., a choice of basis for ). Define a representation on as . Then, associates, to every element of , an invertible matrix.

### Conjugacy class of image

For a finite-dimensional linear representation of , we can associate to every , the conjugacy class of in . This conjugacy class is invariant under equivalence of representations, because any equivalence of representations involves conjugating by an element of .

### Trace and character

`Further information: character of a representation`

For a finite-dimensional linear representation of , we can associate to every , the trace of . (In the concrete situation where and is viewed as a matrix, this is the sum of the diagonal entries of ). Since the trace depends only on the conjugacy class of the representation, it is invariant under equivalence of representations.

The function sending each element of the group to its trace is termed the character of the representation. The character is thus a function from the group to the field.

### Degree

`Further information: Degree of a representation`

The degree of a finite-dimensional linear representation, also called the dimension of the representation, is the dimension of the vector space on which it acts. Equivalently, it is the character evaluated at the identity element of the group.

## Constructions

### Direct sum

`Further information: Direct sum of linear representations`

Let and be two finite-dimensional linear representations. Then, the direct sum of these is given as:

- The vector space for it is
- The action is:

In other words acts component-wise.

If we are thinking of both representations in terms of matrices, i.e. and , then is a block matrix looking like:

### Tensor product

`Further information: Tensor product of linear representations`

**PLACEHOLDER FOR INFORMATION TO BE FILLED IN**: [SHOW MORE]