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.
Highlights
The wireless local area network (WLAN) standard amendment IEEE 802.11s [1,2] integrates basic mesh functions directly into the WLAN link layer, providing the basis for interoperable mesh solutions to realize smart city applications [3,4,5]
We substantially extend CHaChA by mechanisms for cluster adaptation to dynamic topology changes that are likely to occur during longterm network operation and maintenance
These mechanisms include automatic cluster joining of subsequently installed nodes, isolation and fault detection, and node roaming for cluster balancing
Summary
The wireless local area network (WLAN) standard amendment IEEE 802.11s [1,2] integrates basic mesh functions directly into the WLAN link layer, providing the basis for interoperable mesh solutions to realize smart city applications [3,4,5] For this purpose, 802.11s defines mandatory mechanisms for spontaneous networking and message forwarding (routing) between mesh nodes. Unicast message forwarding across multiple hops requires the corresponding number of individual transmissions, so that a mesh path traverses multiple collision domains This is accompanied by the overhead traffic of the WLAN link layer, which is generated, e.g., by periodic announcements (beacons) of the mesh nodes or in the context of the routing protocol. The communication latency and transmission error probability inevitably increase with the number of nodes and average path length in the network
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