Buffering techniques in sleep doze coordination and grid based clustering protocols as power management schemes for wireless sensor networks

IET Conference on Wireless, Mobile and Multimedia Networks Pub Date : 2008-03-12 DOI:10.1049/CP:20080188

A. Roy, Adway Mitra, Arijit Khan, Debashis Saha

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引用次数: 6

Abstract

2 . Abstract- In this paper, we outline an approach to improve the lifespan of a wireless sensor network by introducing a variant to standard sleep synchronization protocols. A multilayered architecture is used. To ensure even higher scalability and lower message size in any particular layer, number of layers is limited to four and each layer is broken into grids. Each grid acts a localized network where data aggregation and lifetime maximization algorithms are being run. In standard sleep protocols like GAF, each grid must have one of its nodes in active state. Our sleep protocol considers one node per grid to be in the idle listening state called the 'doze' state for a fixed interval of time. Thus we propose a three state proactive algorithm in the form of the Sleep Doze Coordination (SDC) protocol to lower the duty cycle of the each sensor node and maximize the network lifespan with lower power consumption. Node buffers are provided to bring about higher data accuracy and lossless network operation. When node buffer gets filled to its capacity by data messages from the lower layer, it signals the 'dozing' node to transit to the active state. Thus the node does not have to remain active throughout its 'on' period and its overall lifespan increases for a given amount of energy. Results indicate that near-optimal performance of SDC is achieved when buffer size is large enough to hold 25 data messages. SDC increases network lifetime by approximately 20% over previous protocols like GAF and S-DMAC.

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无线传感器网络电源管理方案中的缓冲技术和基于网格的聚类协议

２．摘要:在本文中，我们概述了一种通过引入标准睡眠同步协议的变体来提高无线传感器网络寿命的方法。采用了多层体系结构。为了确保在任何特定层中具有更高的可伸缩性和更低的消息大小，层数限制为4层，并且每层都被分成网格。每个网格充当一个局部网络，其中运行数据聚合和生命周期最大化算法。在GAF等标准睡眠协议中，每个网格必须有一个节点处于活动状态。我们的睡眠协议认为每个网格中有一个节点在固定的时间间隔内处于空闲侦听状态，称为“打盹”状态。因此，我们提出了一种以SDC (Sleep - Doze Coordination)协议形式的三状态主动算法，以降低每个传感器节点的占空比，并以较低的功耗最大化网络寿命。提供节点缓冲，提高数据精度，保证网络运行无损。当节点缓冲区被来自底层的数据消息填满其容量时，它向“打盹”节点发出信号，使其转换到活动状态。因此，节点不必在其“开启”期间保持活动状态，并且对于给定的能量量，其总体寿命会增加。结果表明，当缓冲区大小大到足以容纳25条数据消息时，SDC的性能接近最佳。SDC比以前的协议如GAF和S-DMAC增加了大约20%的网络寿命。

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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IET Conference on Wireless, Mobile and Multimedia Networks

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