Cayley's Ω process

In mathematics, Cayley's Ω process, introduced by, is a relatively invariant differential operator on the general linear group, that is used to construct invariants of a group action.

As a partial differential operator acting on functions of n2 variables xij, the omega operator is given by the determinant



\Omega = \begin{vmatrix} \frac{\partial}{\partial x_{11}} & \cdots &\frac{\partial}{\partial x_{1n}} \\ \vdots& \ddots & \vdots\\ \frac{\partial}{\partial x_{n1}} & \cdots &\frac{\partial}{\partial x_{nn}} \end{vmatrix}. $$

For binary forms f in x1, y1 and g in x2, y2 the Ω operator is $$\frac{\partial^2 fg}{\partial x_1 \partial y_2} - \frac{\partial^2 fg}{\partial x_2 \partial y_1}$$. The r-fold Ω process Ωr(f, g) on two forms f and g in the variables x and y is then
 * 1) Convert f to a form in x1, y1 and g to a form in x2, y2
 * 2) Apply the Ω operator r times to the function fg, that is, f times g in these four variables
 * 3) Substitute x for x1 and x2, y for y1 and y2 in the result

The result of the r-fold Ω process Ωr(f, g) on the two forms f and g is also called the r-th transvectant and is commonly written (f, g)r.

Applications
Cayley's Ω process appears in Capelli's identity, which used to find generators for the invariants of various classical groups acting on natural polynomial algebras.

used Cayley's Ω process in his proof of finite generation of rings of invariants of the general linear group. His use of the Ω process gives an explicit formula for the Reynolds operator of the special linear group.

Cayley's Ω process is used to define transvectants.