English

Non-Stationary Queues with Batch Arrivals

Probability 2022-06-20 v3

Abstract

Motivated by applications that involve setting proper staffing levels for multi-server queueing systems with batch arrivals, we present a thorough study of the queue-length process {Q(t);t0}\{Q(t); t \geq 0\}, departure process {D(t);t0}\{D(t); t \geq 0\}, and the workload process {W(t);t0}\{W(t); t \geq 0\} associated with the MtBt_{t}^{B_{t}}/Gt_{t}/\infty queueing system. With two fundamental assumptions of (non-stationary) Poisson arrivals and infinitely many servers, we otherwise maintain a highly general model, in which the service duration and batch size distributions may depend on time and, moreover, where the service durations within a batch may be arbitrarily dependent. Nevertheless, we find that the Poisson and infinite server assumptions are enough to show that for each t>0t > 0, the law of Q(t)Q(t) is that of a weighted sum of mutually independent Poisson random variables. We further invoke this type of decomposition to derive various joint Laplace-Stieltjes transforms associated with the queue-length and departure processes. Next, we study the time-dependent behavior of the workload process, and we conclude by establishing almost sure convergence of the queue-length and workload processes (when properly scaled) to two different shot-noise processes, elevating the weak convergence results shown previously.

Keywords

Cite

@article{arxiv.2008.00625,
  title  = {Non-Stationary Queues with Batch Arrivals},
  author = {Andrew Daw and Brian Fralix and Jamol Pender},
  journal= {arXiv preprint arXiv:2008.00625},
  year   = {2022}
}
R2 v1 2026-06-23T17:35:27.244Z