Large deviation principles induced by the Stiefel manifold, and random multi-dimensional projections

Abstract

Given an n-dimensional random vector X(n) , for k < n, consider its k-dimensional projection an,kX(n), where an,k is an n × k-dimensional matrix belonging to the Stiefel manifold Vn,k of orthonormal k-frames in Rn. For a class of sequences \X(n)\ that includes the uniform distributions on scaled pn balls, p ∈ (1,∞], and product measures with sufficiently light tails, it is shown that the sequence of projected vectors \an,k∫ercal X(n)\ satisfies a large deviation principle whenever the empirical measures of the rows of n an,k converge, as n → ∞, to a probability measure on Rk. In particular, when An,k is a random matrix drawn from the Haar measure on Vn,k, this is shown to imply a large deviation principle for the sequence of random projections \An,k∫ercal X(n)\ in the quenched sense (that is, conditioned on almost sure realizations of \An,k\). Moreover, a variational formula is obtained for the rate function of the large deviation principle for the annealed projections \An,k∫ercal X(n)\, which is expressed in terms of a family of quenched rate functions and a modified entropy term. A key step in this analysis is a large deviation principle for the sequence of empirical measures of rows of n An,k, which may be of independent interest. The study of multi-dimensional random projections of high-dimensional measures is of interest in asymptotic functional analysis, convex geometry and statistics. Prior results on quenched large deviations for random projections of pn balls have been essentially restricted to the one-dimensional setting.