Small Time Convergence of Subordinators with Regularly or Slowly Varying Canonical Measure

Abstract

We consider subordinators Xα=(Xα(t))t 0 in the domain of attraction at 0 of a stable subordinator (Sα(t))t 0 (where α∈(0,1)); thus, with the property that α, the tail function of the canonical measure of Xα, is regularly varying of index -α∈ (-1,0) as x 0. We also analyse the boundary case, α=0, when α is slowly varying at 0. When α∈(0,1), we show that (t α (Xα(t)))-1 converges in distribution, as t 0, to the random variable (Sα(1))α. This latter random variable, as a function of α, converges in distribution as α 0 to the inverse of an exponential random variable. We prove these convergences, also generalised to functional versions (convergence in D[0,1]), and to trimmed versions, whereby a fixed number of its largest jumps up to a specified time are subtracted from a process. The α=0 case produces convergence to an extremal process constructed from ordered jumps of a Cauchy subordinator. Our results generalise random walk and stable process results of Darling, Cressie, Kasahara, Kotani and Watanabe.