Comparison of Energy Harvesting Systems for Wireless Sensor Networks 被引量：26

Comparison of Energy Harvesting Systems for Wireless Sensor Networks

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摘要 Wireless sensor networks (WSNs) offer an attractive solution to many environmental,security,and process monitoring problems.However,one barrier to their fuller adoption is the need to supply electrical power over extended periods of time without the need for dedicated wiring.Energy harvesting provides a potential solution to this problem in many applications.This paper reviews the characteristics and energy requirements of typical sensor network nodes,assesses a range of potential ambient energy sources,and outlines the characteristics of a wide range of energy conversion devices.It then proposes a method to compare these diverse sources and conversion mechanisms in terms of their normalised power density. Wireless sensor networks (WSNs) offer an attractive solution to many environmental,security,and process monitoring problems.However,one barrier to their fuller adoption is the need to supply electrical power over extended periods of time without the need for dedicated wiring.Energy harvesting provides a potential solution to this problem in many applications.This paper reviews the characteristics and energy requirements of typical sensor network nodes,assesses a range of potential ambient energy sources,and outlines the characteristics of a wide range of energy conversion devices.It then proposes a method to compare these diverse sources and conversion mechanisms in terms of their normalised power density.

作者 James M.Gilbert Farooq Balouchi

机构地区 Department of Engineering

出处《International Journal of Automation and computing》 EI 2008年第4期334-347,共14页 国际自动化与计算杂志（英文版）

关键词 Energy harvesting energy scavenging wireless sensor networks (WSNs) energy management Energy harvesting energy scavenging wireless sensor networks (WSNs) energy management

分类号 TP212.9 [自动化与计算机技术—检测技术与自动化装置] TN929.5 [电子电信—通信与信息系统]

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参考文献92

1[1]I.Stojmenovic.Handbook of Sensor Networks:Algorithms and Architectures,John Wiley & Sons Inc,Hoboken,New Jersey,USA,2005.
2[2]R.Jain,J.Wullert II.Challenges:Environmental Design for Pervasive Computing Systems.In Proceedings of the 8th Annual International Conference on Mobile Computing and Networking,ACM,New York,USA,pp.263-270,2002.
3[3]K.Romer,F.Mattern.The Design Space of Wireless Sensor Networks.IEEE Wireless Communications Magazine,vol.11,no.6,pp.54-61,2004.
4[4]K.Martinez,R.Ong,J.K.Hart,J.Stefanov.GLACSWEB:A Sensor Web for Glaciers.In Proceedings of European Workshop on Wireless Sensor Networks,Berlin,Germany,pp.46-49,2004.
5[5]I.W.Marshall,C.Roadknight,I.Wokoma,L.Sacks.Self-organizing Sensor Networks.In Proceedings of UbiNet,London,UK,[Online],Available:http://www-dse.doc.ic.ac.uk/Projects/UbiNet/ws2003/papers/marshall.pdf,2003.
6[6]D.Roemmich,S.Riser,R.Davis,Y.Desanbies.Au-tonomons Profiling Floats:Workhorse for Broadseale Ocean Observations.Marine Technology Society Journal,vol.38,no.1,pp.31-39,2004.
7[7]R.Beekwith,D.Teibel,P.Bowen.Unwired Wine:Sensor Networks in Vineyards.In Proceedings of IEEE Sensors,IEEE Press,vol.2,pp.561-564,2004.
8[8]A.Malnwaring,D.Culler,J.Polastre,R.Szewczyk,J.An-derson.Wireless Sensor Networks for Habitat Monitoring.In Proceedings of the 1st ACM International Workshop on Wireless Sensor Networks and Applications,ACM,Atlanta,Georgia,USA,pp.88-97,2002.
9[9]P.Juang,H.Oki,Y.Wang,M.Martonosi,L.S.Peh,D.Rubenstein.Energy-efficient Computing for Wildlife Track-ing:Design Tradeoffs and Early Experiences with Ze-braNet.In Proceedings of the lOth Architectural Support for Programming Languages and Operating Systems,ACM,San Jose,USA,vol.36,no.5,pp.96-107,2002.
10[10]Z.Butler,P.Corke,R.Peterson,D.Rus.Virtual Fences for Controlling Cows.In Proceedings of IEEE International Conference on Robotics and Automation,IEEE Press,New Orleans,LA,USA,vol.5,pp.4429-4436,2004.

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2林玲,刘辉.压电发电技术研究应用[J].硅谷,2008,1(14):120-120. 被引量：11
3徐可为,高润生,于利根,何家文.薄膜应力测定的X射线掠射法[J].物理学报,1994,43(8):1295-1300. 被引量：15
4郑可炉,褚家如,鲁健,李恒.PZT铁电薄膜湿法刻蚀技术研究[J].压电与声光,2005,27(2):209-212. 被引量：9
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6李宝山,朱志刚,李国荣,殷庆瑞,丁爱丽.铌锰锆钛酸铅压电陶瓷烧结行为的研究[J].无机材料学报,2005,20(4):993-999. 被引量：3
7张邦琨,曾信波.喀斯特森林的土壤温度变化规律[J].土壤,1996,28(1):46-48. 被引量：17
8郭忠文,李之伟,于磊.Lifetime Prolonging Algorithms for Underwater Sensor Networks[J].China Ocean Engineering,2006,20(2):325-334. 被引量：5
9蓝会立,张认成,毛思文.基于无线传感器网络的粮情检测系统设计[J].农机化研究,2006,28(9):99-102. 被引量：19
10颜琳,王小云,全秀娥.动生电动势的产生机理[J].吉首大学学报（自然科学版）,2007,28(1):70-72. 被引量：4

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2王青萍,范跃农,王骐,姜胜林.压电能量收集中储能器件的研究[J].压电与声光,2011,33(6):950-953. 被引量：5
3王青萍,王骐,姜胜林.压电能量收集器的研究现状[J].电子元件与材料,2012,31(2):72-76. 被引量：19
4岐世峰,李艳华.无线粮情监测管理系统的设计与实现[J].四川大学学报（自然科学版）,2012,49(1):75-79. 被引量：5
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7黄如,叶乐,廖怀林.可再生能源互联网中的微电子技术[J].中国科学：信息科学,2014,44(6):728-742. 被引量：18
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1Terrence Mak.Energy-Harvesting Systems for Green Computing[J].Journal of Electronic Science and Technology,2012,10(4):291-295.
2The 11^(th) International Workshop on Piezoelectric Materials and Applications in Actuators and the 9^(th) Energy Harvesting Workshop Held Successfully[J].Transactions of Nanjing University of Aeronautics and Astronautics,2015,32(2).
3Giovanni Bassi Luigi Colalongo Anna Richelli Zsolt Kovacs-Vajna.A 150 mV-1.2 V Fully-Integrated DC-DC Converter for Thermal Energy Harvesting[J].Journal of Energy and Power Engineering,2013,7(4):711-715.
4张华,LIU Yu-liang.Hierarchical self-localization of underwater wireless sensor network nodes[J].Journal of Chongqing University,2013,12(1):41-48.
5裴旭东,陈祥光,刘春涛.New Method for Multivariate Statistical Process Monitoring[J].Journal of Beijing Institute of Technology,2010,19(1):92-98. 被引量：1
6Ting Quan Yingchun Wu Ya Yang.Hybrid electromagnetic-triboelectric nanogenerator for harvesting vibration energy[J].Nano Research,2015,8(10):3272-3280. 被引量：13
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8Jiang-bo YUAN,Xiao-biao SHAN,Tao XIE,Wei-shan CHEN.Science Letters:Energy harvesting with a slotted-cymbal transducer[J].Journal of Zhejiang University-Science A(Applied Physics & Engineering),2009,10(8):1187-1190.
9ZHAO Wei,GUAN Ziyu,CAO Zhengwen,LIU Zheng.Mining and Harvesting High Quality Topical Resources from the Web[J].Chinese Journal of Electronics,2016,25(1):48-57.
10时钟傍上Google[J].西部大开发,2008(11):77-77.

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2008年第4期

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Comparison of Energy Harvesting Systems for Wireless Sensor Networks 被引量：26

参考文献92

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二级引证文献190

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