In abstract algebra, a representation of an associative algebra is a module for that algebra. Here an associative algebra is a ring. If the algebra is not unital, it may be made so in a standard way ; there is no essential difference between modules for the resulting unital ring, in which the identity acts by the identity mapping, and representations of the algebra.
One of the simplest non-trivial examples is a linear complex structure, which is a representation of the complex numbers C, thought of as an associative algebra over the real numbersR. This algebra is realized concretely as which corresponds to. Then a representation of C is a real vector spaceV, together with an action of C on V. Concretely, this is just an action of , as this generates the algebra, and the operator representing is denoted J to avoid confusion with the identity matrixI.
can be generalized to algebra representations. The generalization of an eigenvalue of an algebra representation is, rather than a single scalar, a one-dimensional representation . This is known as a weight, and the analog of an eigenvector and eigenspace are called weight vector and weight space. The case of the eigenvalue of a single operator corresponds to the algebra and a map of algebras is determined by which scalar it maps the generator T to. A weight vector for an algebra representation is a vector such that any element of the algebra maps this vector to a multiple of itself – a one-dimensional submodule. As the pairing is bilinear, "which multiple" is an A-linear functional of A, namely the weight. In symbols, a weight vector is a vector such that for all elements for some linear functional – note that on the left, multiplication is the algebra action, while on the right, multiplication is scalar multiplication. Because a weight is a map to a commutative ring, the map factors through the abelianization of the algebra – equivalently, it vanishes on the derived algebra – in terms of matrices, if is a common eigenvector of operators and, then , so common eigenvectors of an algebra must be in the set on which the algebra acts commutatively. Thus of central interest are the free commutative algebras, namely the polynomial algebras. In this particularly simple and important case of the polynomial algebra in a set of commuting matrices, a weight vector of this algebra is a simultaneous eigenvector of the matrices, while a weight of this algebra is simply a -tuple of scalars corresponding to the eigenvalue of each matrix, and hence geometrically to a point in -space. These weights – in particularly their geometry – are of central importance in understanding the representation theory of Lie algebras, specifically the finite-dimensional representations of semisimple Lie algebras. As an application of this geometry, given an algebra that is a quotient of a polynomial algebra on generators, it corresponds geometrically to an algebraic variety in -dimensional space, and the weight must fall on the variety – i.e., it satisfies defining equations for the variety. This generalizes the fact that eigenvalues satisfy the characteristic polynomial of a matrix in one variable.