Asymptotic Distribution of Bernoulli Quadratic Forms

Abstract

Consider the random quadratic form Tn=Σ1 ≤ u < v ≤ n auv Xu Xv, where ((auv))1 ≤ u, v ≤ n is a \0, 1\-valued symmetric matrix with zeros on the diagonal, and X1, X2, …, Xn are i.i.d. Ber(pn). In this paper, we prove various characterization theorems about the limiting distribution of Tn, in the sparse regime, where 0 < pn 1 such that E(Tn)=O(1). The main result is a decomposition theorem showing that distributional limits of Tn is the sum of three components: a mixture which consists of a quadratic function of independent Poisson variables; a linear Poisson mixture, where the mean of the mixture is itself a (possibly infinite) linear combination of independent Poisson random variables; and another independent Poisson component. This is accompanied with a universality result which allows us to replace the Bernoulli distribution with a large class of other discrete distributions. Another consequence of the general theorem is a necessary and sufficient condition for Poisson convergence, where an interesting second moment phenomenon emerges.