Queue Stability and Probability 1 Convergence via Lyapunov Optimization
Abstract
Lyapunov drift and Lyapunov optimization are powerful techniques for optimizing time averages in stochastic queueing networks subject to stability. However, there are various definitions of queue stability in the literature, and the most convenient Lyapunov drift conditions often provide stability and performance bounds only in terms of a time average expectation, rather than a pure time average. We extend the theory to show that for quadratic Lyapunov functions, the basic drift condition, together with a mild bounded fourth moment condition, implies all major forms of stability. Further, we show that the basic drift-plus-penalty condition implies that the same bounds for queue backlog and penalty expenditure that are known to hold for time average expectations also hold for pure time averages with probability 1. Our analysis combines Lyapunov drift theory with the Kolmogorov law of large numbers for martingale differences with finite variance.
Keywords
Cite
@article{arxiv.1008.3519,
title = {Queue Stability and Probability 1 Convergence via Lyapunov Optimization},
author = {Michael J. Neely},
journal= {arXiv preprint arXiv:1008.3519},
year = {2010}
}
Comments
This version 2 of the paper contains a new and useful theorem (Theorem 3) on rate stability if the quadratic Lyapunov drift is less than or equal to a constant and if second moments of queue changes are bounded