Approximating Systems Fed by Poisson Processes with Rapidly Changing Arrival Rates
Abstract
This paper introduces a new asymptotic regime for simplifying stochastic models having non-stationary effects, such as those that arise in the presence of time-of-day effects. This regime describes an operating environment within which the arrival process to a service system has an arrival intensity that is fluctuating rapidly. We show that such a service system is well approximated by the corresponding model in which the arrival process is Poisson with a constant arrival rate. In addition to the basic weak convergence theorem, we also establish a first order correction for the distribution of the cumulative number of arrivals over , as well as the number-in-system process for an infinite-server queue fed by an arrival process having a rapidly changing arrival rate. This new asymptotic regime provides a second regime within which non-stationary stochastic models can be reasonably approximated by a process with stationary dynamics, thereby complementing the previously studied setting within which rates vary slowly in time.
Cite
@article{arxiv.1807.06805,
title = {Approximating Systems Fed by Poisson Processes with Rapidly Changing Arrival Rates},
author = {Zeyu Zheng and Harsha Honnappa and Peter W. Glynn},
journal= {arXiv preprint arXiv:1807.06805},
year = {2018}
}