English

Supermarket Queueing System in the Heavy Traffic Regime. Short Queue Dynamics

Probability 2017-01-19 v2

Abstract

We consider a queueing system with nn parallel queues operating according to the so-called "supermarket model" in which arriving customers join the shortest of dd randomly selected queues. Assuming rate nλnn\lambda_{n} Poisson arrivals and rate 11 exponentially distributed service times, we consider this model in the heavy traffic regime, described by λn1\lambda_{n}\uparrow 1 as nn\to\infty. We give a simple expectation argument establishing that majority of queues have steady state length at least logd(1λn)1O(1)\log_d(1-\lambda_{n})^{-1} - O(1) with probability approaching one as nn\rightarrow\infty, implying the same for the steady state delay of a typical customer. Our main result concerns the detailed behavior of queues with length smaller than logd(1λn)1O(1)\log_d(1-\lambda_{n})^{-1}-O(1). Assuming λn\lambda_{n} converges to 11 at rate at most n\sqrt{n}, we show that the dynamics of such queues does not follow a diffusion process, as is typical for queueing systems in heavy traffic, but is described instead by a deterministic infinite system of linear differential equations, after an appropriate rescaling. The unique fixed point solution of this system is shown explicitly to be of the form π1(di1)/(d1),i1\pi_{1}(d^{i}-1)/(d-1), i\ge 1, which we conjecture describes the steady state behavior of the queue lengths after the same rescaling. Our result is obtained by combination of several technical ideas including establishing the existence and uniqueness of an associated infinite dimensional system of non-linear integral equations and adopting an appropriate stopped process as an intermediate step.

Keywords

Cite

@article{arxiv.1610.03522,
  title  = {Supermarket Queueing System in the Heavy Traffic Regime. Short Queue Dynamics},
  author = {Patrick Eschenfeldt and David Gamarnik},
  journal= {arXiv preprint arXiv:1610.03522},
  year   = {2017}
}

Comments

39 pages, 1 figure

R2 v1 2026-06-22T16:18:11.750Z