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IEEE 802.11s无线网状网络中的自适应多通道聚类

Adaptive Multi-Channel Clustering in IEEE 802.11s Wireless Mesh Networks.

作者信息

Rethfeldt Michael, Brockmann Tim, Beichler Benjamin, Haubelt Christian, Timmermann Dirk

机构信息

Institute of Applied Microelectronics and Computer Engineering, Faculty of Computer Science and Electrical Engineering, University of Rostock, 18051 Rostock, Germany.

出版信息

Sensors (Basel). 2021 Oct 29;21(21):7215. doi: 10.3390/s21217215.

DOI:10.3390/s21217215
PMID:34770523
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8588358/
Abstract

WLAN mesh networks are one of the key technologies for upcoming smart city applications and are characterized by a flexible and low-cost deployment. The standard amendment IEEE 802.11s introduces low-level mesh interoperability at the WLAN MAC layer. However, scalability limitations imposed by management traffic overhead, routing delays, medium contention, and interference are common issues in wireless mesh networks and also apply to IEEE 802.11s networks. Possible solutions proposed in the literature recommend a divide-and-conquer scheme that partitions the network into clusters and forms smaller collision and broadcast domains by assigning orthogonal channels. We present CHaChA (Clustering Heuristic and Channel Assignment), a distributed cross-layer approach for cluster formation and channel assignment that directly integrates the default IEEE 802.11s mesh protocol information and operating modes, retaining unrestricted compliance to the WLAN standard. Our concept proposes further mechanisms for dynamic cluster adaptation, including subsequent cluster joining, isolation and fault detection, and node roaming for cluster balancing. The practical performance of CHaChA is demonstrated in a real-world 802.11s testbed. We first investigate clustering reproducibility, duration, and communication overhead in static network scenarios of different sizes. We then validate our concepts for dynamic cluster adaptation, considering topology changes that are likely to occur during long-term network operation and maintenance.

摘要

无线局域网(WLAN)网状网络是即将到来的智慧城市应用的关键技术之一,其特点是部署灵活且成本低。标准修正案IEEE 802.11s在WLAN MAC层引入了低级网状网络互操作性。然而,管理流量开销、路由延迟、介质争用和干扰所带来的可扩展性限制是无线网状网络中的常见问题,也适用于IEEE 802.11s网络。文献中提出的可能解决方案推荐了一种分治方案,该方案将网络划分为多个集群,并通过分配正交信道形成更小的冲突域和广播域。我们提出了CHaChA(聚类启发式与信道分配),这是一种用于集群形成和信道分配的分布式跨层方法,它直接集成了默认的IEEE 802.11s网状协议信息和操作模式,同时保持对WLAN标准的无限制合规性。我们的概念提出了进一步的动态集群自适应机制,包括后续集群加入、隔离和故障检测,以及用于集群平衡的节点漫游。CHaChA的实际性能在一个实际的802.11s测试平台上得到了验证。我们首先研究了不同规模静态网络场景下的聚类可重复性、持续时间和通信开销。然后,考虑到长期网络运行和维护期间可能发生的拓扑变化,我们验证了我们的动态集群自适应概念。

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