Spectral Statistics of "Cellular" Billiards

Abstract

For a bounded planar domain 0 whose boundary contains a number of flat pieces i we consider a family of non-symmetric billiards constructed by patching several copies of 0 along i's. It is demonstrated that the length spectrum of the periodic orbits in is degenerate with the multiplicities determined by a matrix group G. We study the energy spectrum of the corresponding quantum billiard problem in and show that it can be split in a number of uncorrelated subspectra corresponding to a set of irreducible representations α of G. Assuming that the classical dynamics in 0 are chaotic, we derive a semiclassical trace formula for each spectral component and show that their energy level statistics are the same as in standard Random Matrix ensembles. Depending on whether α is real, pseudo-real or complex, the spectrum has either Gaussian Orthogonal, Gaussian Symplectic or Gaussian Unitary types of statistics, respectively.