Learning mixtures of structured distributions over discrete domains

Abstract

Let C be a class of probability distributions over the discrete domain [n] = \1,...,n\. We show that if C satisfies a rather general condition -- essentially, that each distribution in C can be well-approximated by a variable-width histogram with few bins -- then there is a highly efficient (both in terms of running time and sample complexity) algorithm that can learn any mixture of k unknown distributions from C. We analyze several natural types of distributions over [n], including log-concave, monotone hazard rate and unimodal distributions, and show that they have the required structural property of being well-approximated by a histogram with few bins. Applying our general algorithm, we obtain near-optimally efficient algorithms for all these mixture learning problems.