Learning Sums of Independent Random Variables with Sparse Collective Support

Abstract

We study the learnability of sums of independent integer random variables given a bound on the size of the union of their supports. For A ⊂ Z+, a sum of independent random variables with collective support A (called an A-sum in this paper) is a distribution S = X1 + ·s + XN where the Xi's are mutually independent (but not necessarily identically distributed) integer random variables with i supp(Xi) ⊂eq A. We give two main algorithmic results for learning such distributions: 1. For the case | A | = 3, we give an algorithm for learning A-sums to accuracy ε that uses poly(1/ε) samples and runs in time poly(1/ε), independent of N and of the elements of A. 2. For an arbitrary constant k ≥ 4, if A = \ a1,...,ak\ with 0 ≤ a1 < ... < ak, we give an algorithm that uses poly(1/ε) · ak samples (independent of N) and runs in time poly(1/ε, ak). We prove an essentially matching lower bound: if |A| = 4, then any algorithm must use ( a4) samples even for learning to constant accuracy. We also give similar-in-spirit (but quantitatively very different) algorithmic results, and essentially matching lower bounds, for the case in which A is not known to the learner.