Channel-quality-aware multihop broadcast for asynchronous multi-channel wireless sensor networks

In this paper, we propose Multi-channel EMBA ( M-EMBA ), efficient multihop broadcast for asynchronous multi-channel wireless sensor networks. Our scheme employs two channel-quality-aware forwarding policies of improved forwarder’s guidance and fast forwarding to improve multihop broadcast performan...

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Veröffentlicht in:	Wireless networks 2016-10, Vol.22 (7), p.2143-2158
Hauptverfasser:	Jang, Ingook, Pyeon, Dohoo, Yoon, Hyunsoo, Kim, Dongwook
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Schlagworte:	Access control Analysis Broadcasting Channels Collisions Communications Engineering Computer Communication Networks Efficiency Electrical Engineering Engineering IT in Business Messages Networks Performance evaluation Policies Protocol Receivers Remote sensors Sensors Simulation Studies Systems design Wireless networks
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container_title	Wireless networks
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creator	Jang, Ingook Pyeon, Dohoo Yoon, Hyunsoo Kim, Dongwook
description	In this paper, we propose Multi-channel EMBA ( M-EMBA ), efficient multihop broadcast for asynchronous multi-channel wireless sensor networks. Our scheme employs two channel-quality-aware forwarding policies of improved forwarder’s guidance and fast forwarding to improve multihop broadcast performance. The improved forwarder’s guidance allows forwarders to transmit broadcast messages with guidance to their receivers through channels with good quality. The guidance indicates how each receiver should forward the broadcast message to its neighbor nodes. The improved forwarder’s guidance tremendously reduces redundant transmissions and collisions. Fast forwarding allows adjacent forwarders to send their broadcast messages simultaneously through different channels that have good quality, which helps to reduce multihop broadcast latency and improve multi-channel broadcast utility. In this work, we evaluate the multihop broadcast performance of M-EMBA through theoretical analysis of the system design and empirical simulation-based analysis. We implement M-EMBA in ns-2 and compare it with the broadcast schemes of ARM, EM-MAC, and MuchMAC. The performance results show that M-EMBA outperforms these protocols in both light and heavy network traffic. M-EMBA reduces message cost in terms of goodput, total bytes transmitted, as well as broadcast redundancy and collision. M-EMBA also achieves a high broadcast success ratio and low multihop broadcast latency. Finally, M-EMBA significantly improves energy efficiency by reducing average duty cycle.
doi_str_mv	10.1007/s11276-015-1088-8
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We implement M-EMBA in ns-2 and compare it with the broadcast schemes of ARM, EM-MAC, and MuchMAC. The performance results show that M-EMBA outperforms these protocols in both light and heavy network traffic. M-EMBA reduces message cost in terms of goodput, total bytes transmitted, as well as broadcast redundancy and collision. M-EMBA also achieves a high broadcast success ratio and low multihop broadcast latency. Finally, M-EMBA significantly improves energy efficiency by reducing average duty cycle.</abstract><cop>New York</cop><pub>Springer US</pub><doi>10.1007/s11276-015-1088-8</doi><tpages>16</tpages></addata></record>
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subjects	Access control Analysis Broadcasting Channels Collisions Communications Engineering Computer Communication Networks Efficiency Electrical Engineering Engineering IT in Business Messages Networks Performance evaluation Policies Protocol Receivers Remote sensors Sensors Simulation Studies Systems design Wireless networks
title	Channel-quality-aware multihop broadcast for asynchronous multi-channel wireless sensor networks
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