Convergence to scale-invariant Poisson processes and applications in Dickman approximation

Abstract

We study weak convergence of a sequence of point processes to a scale-invariant simple point process. For a deterministic sequence (zn)n∈N of positive real numbers increasing to infinity as n ∞ and a sequence (Xk)k∈N of independent non-negative integer-valued random variables, we consider the sequence of point processes equation* n=Σk=1∞ Xk δzk/zn, n∈ N, equation* and prove that, under some general conditions, it converges vaguely in distribution to a scale-invariant Poisson process ηc on (0,∞) with the intensity measure having the density ct-1, t∈(0,∞). An important motivating example from probabilistic number theory relies on choosing Xk Geom(1-1/pk) and zk= pk, k∈ N, where (pk)k ∈ N is an enumeration of the primes in increasing order. We derive a general result on convergence of the integrals ∫01 t n(dt) to the integral ∫01 t ηc(dt), the latter having a generalized Dickman distribution, thus providing a new way of proving Dickman convergence results. We extend our results to the multivariate setting and provide sufficient conditions for vague convergence in distribution for a broad class of sequences of point processes obtained by mapping the points from (0,∞) to Rd via multiplication by i.i.d. random vectors. In addition, we introduce a new class of multivariate Dickman distributions which naturally extends the univariate setting.