Research Article
Distributed contention-aware call admission control for IEEE 802.11 multi-radio multi-rate multi-channel wireless mesh networks
@INPROCEEDINGS{10.4108/ICST.QSHINE2008.3941, author={Tehuang Liu and Wanjiun Liao}, title={Distributed contention-aware call admission control for IEEE 802.11 multi-radio multi-rate multi-channel wireless mesh networks}, proceedings={5th International ICST Conference on Heterogeneous Networking for Quality, Reliability, Security and Robustness}, publisher={ICST}, proceedings_a={QSHINE}, year={2010}, month={5}, keywords={wireless mesh networks call admission control multi-radio multi-rate multi-channel}, doi={10.4108/ICST.QSHINE2008.3941} }- Tehuang Liu
Wanjiun Liao
Year: 2010
Distributed contention-aware call admission control for IEEE 802.11 multi-radio multi-rate multi-channel wireless mesh networks
QSHINE
ICST
DOI: 10.4108/ICST.QSHINE2008.3941
Abstract
In this paper, we focus on call admission control (CAC) in IEEE 802.11 multi-radio multi-rate multi-channel (MR2-MC) wireless mesh networks (WMNs). CAC is the key component of QoS routing protocols. The goal of CAC is to protect existing flows from QoS violations and fully utilize available radio resource on channels. We propose a CAC mechanism, called Contention-Aware Multi-channel Call Admission Control (CMC), for MR2-MC WMNs based on IEEE 802.11 DCF. CMC is fully distributed, relies on local information to estimate the residual bandwidth of a path, and can be integrated into existing routing protocols for MR2-MC WMNs to provide QoS. We evaluate the performance of CMC via ns-2 simulations. The results show that CMC can precisely predict the end-to-end residual bandwidths of paths, successfully protects existing flows from QoS violations, and fully utilizes the bandwidths on channels.