Decentralized time-synchronized channel swapping

Proceedings of the 14th International Conference on Information Processing in Sensor Networks Pub Date : 2015-04-13 DOI:10.1145/2737095.2742557

G. Smart, N. Deligiannis, J. Mota, Y. Andreopoulos

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引用次数: 1

Abstract

We are working on a new concept for decentralized medium access control (MAC), termed decentralized time-synchronized channel swapping (DT-SCS). Under the proposed DT-SCS and its associated MAC-layer protocol, wireless nodes converge to synchronous beacon packet transmissions across all IEEE802.15.4 channels, with balanced numbers of nodes in each channel. This is achieved by reactive listening mechanisms, based on pulse coupled oscillator techniques. Once convergence to the multichannel time-synchronized state is achieved, peer-to-peer channel swapping can then take place via swap requests and acknowledgments made by concurrent transmitters in neighboring channels. Our implementation of DT-SCS reveals that our proposal comprises an excellent candidate for completely decentralized MAC-layer coordination in WSNs by providing for quick convergence to steady state, high bandwidth utilization, high connectivity and robustness to interference and hidden nodes. The demo will showcase the properties of DT-SCS and will also present its behaviour under various scenarios for hidden nodes and interference, both experimentally and with the help of visualization of simulation results.

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分散的时间同步通道交换

我们正在研究一种新的去中心化媒体访问控制(MAC)概念，称为去中心化时间同步信道交换(DT-SCS)。在提议的DT-SCS及其相关的mac层协议下，无线节点在所有IEEE802.15.4通道上汇聚到同步信标数据包传输，每个通道中的节点数量均衡。这是通过基于脉冲耦合振荡器技术的响应式监听机制实现的。一旦收敛到多通道时间同步状态，对等通道交换就可以通过交换请求和相邻通道中并发发送器的确认进行。我们对DT-SCS的实现表明，我们的提议包含了wsn中完全分散的mac层协调的优秀候选，提供了快速收敛到稳态，高带宽利用率，高连接性以及对干扰和隐藏节点的鲁棒性。演示将展示DT-SCS的特性，并将通过实验和仿真结果的可视化来展示其在隐藏节点和干扰的各种场景下的行为。

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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Proceedings of the 14th International Conference on Information Processing in Sensor Networks

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