A Hal\'asz-type theorem for permutation anticoncentration

Abstract

Given a set A=\a1,…,an\ of real numbers and real coefficients b1,…,bn, consider the distribution of the sum obtained by pairing the ai's with the bi's according to a uniformly random permutation. A recent theorem of Pawlowski shows that as soon as the coefficients are not all equal, this distribution is always spread out at scale n-1: no single value can occur with probability larger than 12 n/2 + 1, and this bound is sharp in general. We show that stronger anticoncentration holds when the coefficients have additional diversity. We quantify the structure of the coefficient multiset by a simple statistic depending on its multiplicity profile, and prove that the maximum point mass of the permuted sum decays polynomially faster as this statistic grows. In particular, when the coefficients are all distinct we obtain a bound of n-5/2+o(1), which can be regarded as an analogue of a classical theorem of Erdos and Moser.