Abstract

We numerically investigate statistical properties of short-wavelength normal modes and the spectrum for the Helmholtz equation in a two-dimensional stadium-shaped region. As the geometrical optics rays within this boundary (billiards) are nonintegrable, this wave problem serves as a simple model for the study of quantum chaos. The local spatial correlation function 〈${\ensuremath{\psi}}_{n}$(x+(1/2s)${\mathrm{\ensuremath{\psi}}}_{\mathrm{n}}$(x- 1) / 2 s)〉 and the probability distribution ${P}_{n}$(\ensuremath{\psi}) of wave amplitude for normal modes ${\ensuremath{\psi}}_{n}$ are computed and compared with predictions based on semiclassical arguments applied to this nonintegrable Hamiltonian. The spectrum is analyzed in terms of the probability P(\ensuremath{\Delta}E) of neighboring energy-eigenvalue separations, which is shown to be similar to a Wigner distribution for the eigenvalues of a random matrix.