Sliding contention window (SCW): towards backoff range-based service differentiation over IEEE 802.11 wireless LAN networks

A number of works have tried to adjust the contention window in order to provide differentiated quality of service in IEEE 802.11-based wireless networks. By giving different service classes different CWs, the distribution of backoff intervals (chosen randomly, on the interval [O, CW]) will reflect...

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Published in:IEEE network 2005-07, Vol.19 (4), p.45-51
Main Authors: Nafaa, A., Ksentini, A., Mehaoua, A., lshibashi, B., Iraqi, Y., Boutaba, R.
Format: Article
Language:English
Subjects:
Adjustment
Bandwidth
Codecs
Error correction
Intervals
Laboratories
Local area networks
Media Access Protocol
Networks
Protocol (computers)
Quality of service
Separation
Simulation
Sliding
Telecommunication traffic
Traffic control
Utilization
Wireless LAN
Wireless networks
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cited_by cdi_FETCH-LOGICAL-c355t-46a5ad6fc01b9bf413623fb7110e204b3876781c669424143569282bcd90a7753
cites cdi_FETCH-LOGICAL-c355t-46a5ad6fc01b9bf413623fb7110e204b3876781c669424143569282bcd90a7753
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creator Nafaa, A.
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Mehaoua, A.
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Iraqi, Y.
Boutaba, R.
description A number of works have tried to adjust the contention window in order to provide differentiated quality of service in IEEE 802.11-based wireless networks. By giving different service classes different CWs, the distribution of backoff intervals (chosen randomly, on the interval [O, CW]) will reflect the desired service classes. However, these protocols cannot deliver firm service guarantees while maintaining high network utilization, particularly under congested network conditions. In this article we propose a new MAC protocol featuring a sliding CW (SCW) for each network flow. The SCW dynamically adjusts to changing network conditions, but remains within a per-class predefined range in order to maintain a separation between different service classes. Each flow's SCW reacts based on the degree to which class-defined QoS metrics are satisfied. Simulation results show that compared to the enhanced distributed coordination function (EDCF) scheme of 802.11e, SCW consistently excels, in terms of network utilization, strict service separation, and service-level fairness.
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ispartof IEEE network, 2005-07, Vol.19 (4), p.45-51
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source IEEE Electronic Library (IEL) Journals
subjects Adjustment
Bandwidth
Codecs
Error correction
Intervals
Laboratories
Local area networks
Media Access Protocol
Networks
Protocol (computers)
Quality of service
Separation
Simulation
Sliding
Telecommunication traffic
Traffic control
Utilization
Wireless LAN
Wireless networks
title Sliding contention window (SCW): towards backoff range-based service differentiation over IEEE 802.11 wireless LAN networks
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