Learning Mixtures of Spherical Gaussians via Fourier Analysis

Abstract

Suppose that we are given independent, identically distributed samples xl from a mixture μ of no more than k of d-dimensional spherical gaussian distributions μi with variance 1, such that the minimum 2 distance between two distinct centers yl and yj is greater than d for some c ≤ , where c∈ (0,1) is a small positive universal constant. We develop a randomized algorithm that learns the centers yl of the gaussians, to within an 2 distance of δ < d2 and the weights wl to within cwmin with probability greater than 1 - (-k/c). The number of samples and the computational time is bounded above by poly(k, d, 1δ). Such a bound on the sample and computational complexity was previously unknown when ω(1) ≤ d ≤ O( k). When d = O(1), this follows from work of Regev and Vijayaraghavan. These authors also show that the sample complexity of learning a random mixture of gaussians in a ball of radius (d) in d dimensions, when d is ( k) is at least poly(k, 1δ), showing that our result is tight in this case.