Projections of the uniform distribution on the cube -- a large deviation perspective

Abstract

Let (n) be a random vector uniformly distributed on the unit sphere Sn-1 in Rn. Consider the projection of the uniform distribution on the cube [-1,1]n to the line spanned by (n). The projected distribution is the random probability measure μ(n) on R given by \[ μ(n)(A) := 1 2n ∫[-1,1]n 1\ u, (n) ∈ A\ du, \] for Borel subets A of R. It is well known that, with probability 1, the sequence of random probability measures μ(n) converges weakly to the centered Gaussian distribution with variance 1/3. We prove a large deviation principle for the sequence μ(n) on the space of probability measures on R with speed n. The (good) rate function is explicitly given by I((α)) := - 12 ( 1 - \|α\|22) whenever (α) is the law of a random variable of the form align* 1 - \|α\|22 Z 3 + Σ k = 1∞ αk Uk, align* where Z is standard Gaussian independent of U1,U2,… which are i.i.d. Unif[-1,1], and α1 ≥ α2 ≥ … is a non-increasing sequence of non-negative reals with \|α\|2<1. We obtain a similar result for random projections of the uniform distribution on the discrete cube \-1,+1\n.