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引用次数: 8
摘要
主动射频识别(a - rfid)是一种技术,其中标签(转发器)携带车载能量源,为无线电、处理器电路和传感器供电。除了在RFID阅读器和标签之间提供比无源RFID更长的工作距离外,这也使标签能够在标签附近没有RFID阅读器的情况下进行传感器测量,计算和存储。本文介绍了一种介质访问数据通信协议,该协议可以动态调整其后退算法,以最佳地适应手头的实际有源RFID应用。基于CSMA/CA (Carrier Sense Multiple Access / Collision Avoidance) a - rfid协议中几种典型退退算法对标签能量成本、读出延迟和消息吞吐量的影响的仿真研究,我们得出结论,通过动态调整初始竞争窗口大小和退退间隔系数,可以显著降低标签能量消耗和读出延迟。我们也提供了具体的指导方针,说明如何在各种应用限制下选择参数(即最大读出延迟;和传递的标签数量)。
An application dependent medium access protocol for active RFID using dynamic tuning of the back-off algorithm
Active Radio Frequency Identification (A-RFID) is a technology where the tags (transponders) carry an on-board energy source for powering the radio, processor circuits, and sensors. Besides offering longer working distance between RFID-reader and tag than passive RFID, this also enables the tags to do sensor measurements, calculations and storage even when no RFID-reader is in the vicinity of the tags. In this paper we introduce a medium access data communication protocol which dynamically adjusts its back-off algorithm to best suit the actual active RFID application at hand. Based on a simulation study of the effect on tag energy cost, readout delay, and message throughput incurred by some typical back-off algorithms in a CSMA/CA (Carrier Sense Multiple Access / Collision Avoidance) A-RFID protocol, we conclude that by dynamic tuning of the initial contention window size and back-off interval coefficient, tag energy consumption and read-out delay can be significantly lowered. We also present specific guidelines on how parameters should be selected under various application constraints (viz. maximum readout delay; and the number of tags passing).
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