Fairness and Load Balancing in Wireless LANs Using Association Control

The traffic load of wireless LANs is often unevenly distributed among the access points (APs), which results in unfair bandwidth allocation among users. We argue that the load imbalance and consequent unfair bandwidth allocation can be greatly reduced by intelligent association control. In this pape...

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Veröffentlicht in:	IEEE/ACM transactions on networking 2007-06, Vol.15 (3), p.560-573
Hauptverfasser:	Bejerano, Y., Seung-Jae Han, Li Li
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Allocations Approximation algorithms Associations Bandwidth Bandwidths Channel allocation Heuristic algorithms IEEE 802.11 WLANs Intelligent control Load balancing Load balancing (computing) Load management Local area networks Mathematical models max-min fairness Optimization Polynomials Product introduction Telecommunication traffic Throughput Wireless LAN
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creator	Bejerano, Y. Seung-Jae Han Li Li
description	The traffic load of wireless LANs is often unevenly distributed among the access points (APs), which results in unfair bandwidth allocation among users. We argue that the load imbalance and consequent unfair bandwidth allocation can be greatly reduced by intelligent association control. In this paper, we present an efficient solution to determine the user-AP associations for max-min fair bandwidth allocation. We show the strong correlation between fairness and load balancing, which enables us to use load balancing techniques for obtaining optimal max-min fair bandwidth allocation. As this problem is NP-hard, we devise algorithms that achieve constant-factor approximation. In our algorithms, we first compute a fractional association solution, in which users can be associated with multiple APs simultaneously. This solution guarantees the fairest bandwidth allocation in terms of max-min fairness. Then, by utilizing a rounding method, we obtain the integral solution from the fractional solution. We also consider time fairness and present a polynomial-time algorithm for optimal integral solution. We further extend our schemes for the on-line case where users may join and leave dynamically. Our simulations demonstrate that the proposed algorithms achieve close to optimal load balancing (i.e., max-min fairness) and they outperform commonly used heuristics.
doi_str_mv	10.1109/TNET.2007.893680
format	Article
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subjects	Algorithms Allocations Approximation algorithms Associations Bandwidth Bandwidths Channel allocation Heuristic algorithms IEEE 802.11 WLANs Intelligent control Load balancing Load balancing (computing) Load management Local area networks Mathematical models max-min fairness Optimization Polynomials Product introduction Telecommunication traffic Throughput Wireless LAN
title	Fairness and Load Balancing in Wireless LANs Using Association Control
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