Upper Bounds for Symmetric Approximate Bounded Indistinguishability

Abstract

A pair of probability distributions over \0,1\n is said to be (k,δ)-wise indistinguishable if all of the size k marginals are within statistical distance at most δ. Previous works introduced this concept and study when and how well one can distinguish between such a pair of symmetric distributions by observing t bits. We use a simple hypergeometric smoothing approach and Hahn polynomials to obtain new upper bounds that apply across a wider range of parameters and improve previously available bounds in several regimes. In particular, prior works left open the basic question of whether there exist constants 0<c1<c2<1 and a pair of (c1n,0)-wise indistinguishable distributions such that the c2n-wise marginals have statistical distance Ω(1). One application of our new bounds is to rule this out for all c1,c2 and to show that the c2n-wise marginals must in fact be exponentially close. Another application in this setting is to show that the c2n-wise marginals must be super-polynomially close even if the c1n-wise marginals are allowed to have statistical distance δ for any δ≤(-ω(nn)). Our bounds also yield new results in other regimes, for example when k is sublinear or when t/n tends to 1.