Upper tails for arithmetic progressions revisited

Abstract

Let X be the number of k-term arithmetic progressions contained in the p-biased random subset of the first N positive integers. We give asymptotically sharp estimates on the logarithmic upper-tail probability (X E[X] + t) for all (N-2/k) p 1 and all t Var(X), excluding only a few boundary cases. In particular, we show that the space of parameters (p,t) is partitioned into three phenomenologically distinct regions, where the upper-tail probabilities either resemble those of Gaussian or Poisson random variables, or are naturally described by the probability of appearance of a small set that contains nearly all of the excess t progressions. We employ a variety of tools from probability theory, including classical tilting arguments and martingale concentration inequalities. However, the main technical innovation is a combinatorial result that establishes a stronger version of `entropic stability' for sets with rich arithmetic structure.