English

Performance Guarantee under Longest-Queue-First Schedule in Wireless Networks

Information Theory 2011-07-19 v1 math.IT

Abstract

Efficient link scheduling in a wireless network is challenging. Typical optimal algorithms require solving an NP-hard sub-problem. To meet the challenge, one stream of research focuses on finding simpler sub-optimal algorithms that have low complexity but high efficiency in practice. In this paper, we study the performance guarantee of one such scheduling algorithm, the Longest-Queue-First (LQF) algorithm. It is known that the LQF algorithm achieves the full capacity region, Λ\Lambda, when the interference graph satisfies the so-called local pooling condition. For a general graph GG, LQF achieves (i.e., stabilizes) a part of the capacity region, σ(G)Λ\sigma^*(G) \Lambda, where σ(G)\sigma^*(G) is the overall local pooling factor of the interference graph GG and σ(G)1\sigma^*(G) \leq 1. It has been shown later that LQF achieves a larger rate region, Σ(G)Λ\Sigma^*(G) \Lambda, where Σ(G)\Sigma^ (G) is a diagonal matrix. The contribution of this paper is to describe three new achievable rate regions, which are larger than the previously-known regions. In particular, the new regions include all the extreme points of the capacity region and are not convex in general. We also discover a counter-intuitive phenomenon in which increasing the arrival rate may sometime help to stabilize the network. This phenomenon can be well explained using the theory developed in the paper.

Keywords

Cite

@article{arxiv.1107.3199,
  title  = {Performance Guarantee under Longest-Queue-First Schedule in Wireless Networks},
  author = {Bo Li and Cem Boyaci and Ye Xia},
  journal= {arXiv preprint arXiv:1107.3199},
  year   = {2011}
}

Comments

27 pages, 7 figures

R2 v1 2026-06-21T18:37:45.150Z