SATS: An Ultra-Low Power Time Synchronization for Solar Energy Harvesting WSNs

Proceedings of the 2016 International Symposium on Low Power Electronics and Design Pub Date : 2016-08-08 DOI:10.1145/2934583.2934601

Tongda Wu, Yongpan Liu, Hehe Li, C. Xue, H. Lee, Huazhong Yang

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引用次数: 3

Abstract

Reliable and ultra-low power time synchronization becomes more and more important with the popularity of energy harvesting sensor nodes. This paper proposes an untethered and probabilistic ultra-lower power time synchronization method for energy intermittent sensor network. It avoids the frequent RF communications with the assistance of a solar clock. The SATS system consists of two main parts: the synchronizer, a low power solar clock module for time synchronization, and the S3-Mapping, an offline sequence matching algorithm. Furthermore, we develop an improved version of S3-Mapping, which reduces the computation complexity from exponential to linear using the redundancy models and the onion peeling method. The SATS system is validated by both simulations and a prototype, which shows that the second level synchronization precision can be achieved under reasonable probability. What's more, the energy consumption of time synchronization is reduced by over 1 ~ 2 magnitudes compared with the up-to-date low power time synchronization protocol.

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SATS:太阳能收集WSNs的超低功率时间同步

随着能量采集传感器节点的普及，可靠和超低功耗的时间同步变得越来越重要。针对能量间歇传感器网络，提出了一种无约束的概率超低功耗时间同步方法。它避免了在太阳能时钟的帮助下频繁的射频通信。SATS系统由两个主要部分组成:同步器，用于时间同步的低功耗太阳能时钟模块，以及离线序列匹配算法S3-Mapping。在此基础上，我们开发了一种改进的S3-Mapping算法，利用冗余模型和洋葱剥离方法将计算复杂度从指数型降低到线性型。仿真和样机验证了SATS系统在合理的概率下可以达到二级同步精度。与现有的低功耗时间同步协议相比，该协议的时间同步能耗降低了1 ~ 2个量级。

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 2016 International Symposium on Low Power Electronics and Design

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