不丢失带宽:自适应传输功率和多跳拓扑控制

2017 13th International Conference on Distributed Computing in Sensor Systems (DCOSS) Pub Date : 2017-06-05 DOI:10.1109/DCOSS.2017.23

Hyung-Sin Kim, Jeongyeup Paek, D. Culler, S. Bahk

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引用次数: 25

摘要

研究表明，在传输功率和路由拓扑共同自适应控制的情况下，多跳无线网络可以获得更好的带宽和路由稳定性。我们的实验表明，基于“链路质量和跳距”的路由拓扑结构的主流“固定和均匀”传输功率策略由于隐藏终端和负载不平衡问题而损失了大量带宽。我们在标准RPL路由协议中设计了一种自适应的分布式控制机制，用于传输功率和路由拓扑PCRPL。我们在真实的嵌入式设备上实现了PC-RPL，并在49节点多跳测试台上评估了其性能。与传输功率最高的RPL相比，PC-RPL在不增加跳距离的情况下，将端到端总丢包量减少了7倍，使总带宽提高了17%，最坏情况下的节点带宽提高了64%。

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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Do Not Lose Bandwidth: Adaptive Transmission Power and Multihop Topology Control

We show that a multihop wireless network can achieve better bandwidth and routing stability when transmission power and routing topology are jointly and adaptively controlled. Our experiments show that the predominant 'fixed and uniform' transmission power strategy with 'link quality and hop distance'-based routing topology construction loses significant bandwidth due to hidden terminal and load imbalance problems. We design an adaptive and distributed control mechanism for transmission power and routing topology, PCRPL, within the standard RPL routing protocol. We implement PC-RPL on real embedded devices and evaluate its performance on a 49-node multihop testbed. PC-RPL reduces total end-to-end packet losses ~7-fold without increasing hop distance compared to RPL with the highest transmission power, resulting in 17% improvement in aggregate bandwidth and 64% for the worst-case node.

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来源期刊

2017 13th International Conference on Distributed Computing in Sensor Systems (DCOSS)

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