A new look at random projections of the cube and general product measures

Abstract

A strong law of large numbers for d-dimensional random projections of the n-dimensional cube is derived. It shows that with respect to the Hausdorff distance a properly normalized random projection of [-1,1]n onto Rd almost surely converges to a centered d-dimensional Euclidean ball of radius 2/π, as n∞. For every point inside this ball we determine the asymptotic number of vertices and the volume of the part of the cube projected `close' to this point. Moreover, large deviations for random projections of general product measures are studied. Let n be the n-fold product measure of a Borel probability measure on R, and let I be uniformly distributed on the Stiefel manifold of orthogonal d-frames in Rn. It is shown that the sequence of random measures n(n-1/2I*)-1, n∈N, satisfies a large deviations principle with probability 1. The rate function is explicitly identified in terms of the moment generating function of . At the heart of the proofs lies a transition trick which allows to replace the uniform projection by the Gaussian one. A number of concrete examples are discussed as well, including the uniform distributions on the cube [-1,1]n and the discrete cube \-1,1\n as a special cases.