In mathematics, the **hypergeometric function of a matrix argument** is a generalization of the classical hypergeometric series. It is a function defined by an infinite summation which can be used to evaluate certain multivariate integrals.

Hypergeometric functions of a matrix argument have applications in random matrix theory. For example, the distributions of the extreme eigenvalues of random matrices are often expressed in terms of the hypergeometric function of a matrix argument.

Let and be integers, and let be an complex symmetric matrix. Then the hypergeometric function of a matrix argument and parameter is defined as

where means is a partition of , is the generalized Pochhammer symbol, and is the "C" normalization of the Jack function.

If and are two complex symmetric matrices, then the hypergeometric function of two matrix arguments is defined as:

where is the identity matrix of size .

Unlike other functions of matrix argument, such as the matrix exponential, which are matrix-valued, the hypergeometric function of (one or two) matrix arguments is scalar-valued.

In many publications the parameter is omitted. Also, in different publications different values of are being implicitly assumed. For example, in the theory of real random matrices (see, e.g., Muirhead, 1984), whereas in other settings (e.g., in the complex case—see Gross and Richards, 1989), . To make matters worse, in random matrix theory researchers tend to prefer a parameter called instead of which is used in combinatorics.

The thing to remember is that

Care should be exercised as to whether a particular text is using a parameter or and which the particular value of that parameter is.

Typically, in settings involving real random matrices, and thus . In settings involving complex random matrices, one has and .