Exact asymptotics for a multi-timescale model, with applications in modeling overdispersed customer streams

Abstract

In this paper we study the probability n(u):= P(Cn≥slant u n ), with Cn:=A(n B(n)) for L\'evy processes A(·) and B(·), and n and n non-negative sequences such that n n =n and n∞ as n∞. Two timescale regimes are distinguished: a `fast' regime in which n is superlinear and a `slow' regime in which n is sublinear. We provide the exact asymptotics of n(u) (as n∞) for both regimes, relying on change-of-measure arguments in combination with Edgeworth-type estimates. The asymptotics have an unconventional form: the exponent contains the commonly observed linear term, but may also contain sublinear terms (the number of which depends on the precise form of n and n). To showcase the power of our results we include two examples, covering both the case where Cn is lattice and non-lattice. Finally we present numerical experiments that demonstrate the importance of taking into account the doubly stochastic nature of Cn in a practical application related to customer streams in service systems; they show that the asymptotic results obtained yield highly accurate approximations, also in scenarios in which there is no pronounced timescale separation.