SOSMAC: Separated operation states in Medium Access Control for emergency communications on IEEE 802.11-like crowded networks

2017 26th Wireless and Optical Communication Conference (WOCC) Pub Date : 2017-04-01 DOI:10.1109/WOCC.2017.7928977

Paa Kwesi Esubonteng, R. Rojas-Cessa

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引用次数: 2

Abstract

We propose a sequential staging access scheme to minimize the occurrence of channel-access collisions in infrastructure IEEE 802.11 (WiFi) networks under emergency and crowded scenarios in this paper. The proposed scheme is based on separating the functions performed by station for channel access and dedicating states for contention and transmission separately rather than using a single shared state as done in IEEE 802.11. The result is an increase in access success ratio and avoidance of throughput collapse 802.11. The proposed scheme overcomes the throughput and utilization collapse of IEEE 802.11 under crowded scenarios and increases bandwidth utilization. This access is critical for crowded networks under emergency scenarios where many stations suddenly and intensively contend for network access. This scheme may also fits as a fallback mechanism of IEEE 802.11 networks to avoid throughput collapse under crowded scenarios and thus, to enable reliable communications in critical situations. Our simulation results show significant improvements on bandwidth utilization and throughput as compared to IEEE 802.11 under crowded conditions.

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SOSMAC:在IEEE 802.11类拥挤网络中用于紧急通信的介质访问控制中的分离操作状态

本文提出了一种顺序分段接入方案，以最大限度地减少紧急和拥挤场景下基础设施IEEE 802.11 (WiFi)网络中信道接入冲突的发生。所提出的方案是基于将站所执行的用于信道访问的功能和用于争用和传输的专用状态分开，而不是像IEEE 802.11那样使用单一的共享状态。其结果是增加了访问成功率并避免了802.11的吞吐量崩溃。该方案克服了IEEE 802.11在拥挤场景下吞吐量和利用率崩溃的问题，提高了带宽利用率。在紧急情况下，当许多站点突然和激烈地争夺网络接入时，这种接入对拥挤的网络至关重要。该方案也可以作为IEEE 802.11网络的回退机制，以避免拥挤场景下的吞吐量崩溃，从而实现关键情况下的可靠通信。我们的模拟结果显示，在拥挤的条件下，与IEEE 802.11相比，带宽利用率和吞吐量有了显著的提高。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2017 26th Wireless and Optical Communication Conference (WOCC)

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