Bivariate fluctuations for the number of arithmetic progressions in random sets

Abstract

We study arithmetic progressions \a,a+b,a+2b,…,a+(-1) b\, with 3, in random subsets of the initial segment of natural numbers [n]:=\1,2,…, n\. Given p∈[0,1] we denote by [n]p the random subset of [n] which includes every number with probability p, independently of one another. The focus lies on sparse random subsets, i.e.\ when p=p(n)=o(1) as n+∞. Let X denote the number of distinct arithmetic progressions of length which are contained in [n]p. We determine the limiting distribution for X not only for fixed 3 but also when =(n)+∞. The main result concerns the joint distribution of the pair (X,X'), >', for which we prove a bivariate central limit theorem for a wide range of p. Interestingly, the question of whether the limiting distribution is trivial, degenerate, or non-trivial is characterised by the asymptotic behaviour (as n+∞) of the threshold function =(n):=np-1. The proofs are based on the method of moments and combinatorial arguments, such as an algorithmic enumeration of collections of arithmetic progressions.