Weak convergence of renewal shot noise processes in the case of slowly varying normalization

Abstract

We investigate weak convergence of finite-dimensional distributions of a renewal shot noise process (Y(t))t≥ 0 with deterministic response function h and the shots occurring at the times 0 = S0 < S1 < S2<…, where (Sn) is a random walk with i.i.d.\ jumps. There has been an outbreak of recent activity around this topic. We are interested in one out of few cases which remained open: h is regularly varying at ∞ of index -1/2 and the integral of h2 is infinite. Assuming that S1 has a moment of order r>2 we use a strong approximation argument to show that the random fluctuations of Y(s) occur on the scale s=t+g(t,u) for u∈ [0,1], as t∞, and, on the level of finite-dimensional distributions, are well approximated by the sum of a Brownian motion and a Gaussian process with independent values (the two processes being independent). The scaling function g above depends on the slowly varying factor of h. If, for instance, t∞t1/2h(t)∈ (0,∞), then g(t,u)=tu.