A power harvester for wireless sensing applications

被引:38
|
作者
Casciati, Fabio
Rossi, Roberto
机构
[1] Pavia Syst SAS, I-27100 Pavia, Italy
[2] Univ Pavia, Dept Struct Mech, I-27100 Pavia, Italy
来源
STRUCTURAL CONTROL & HEALTH MONITORING | 2007年 / 14卷 / 04期
关键词
battery; power harvesting; power storage; semiactive control device; sensors; vibration;
D O I
10.1002/stc.179
中图分类号
TU [建筑科学];
学科分类号
0813 ;
摘要
In many implementations of structural monitoring, wires connecting the sensors in a chain or in a network are not allowed. Furthermore, most of the sensors are supposed to work just after a triggering event, so that they only absorb energy during a limited number of short working periods. Nevertheless, power harvesting is the weak link in conceiving a fully wireless architecture. The overall problem is discussed throughout this paper and solutions for specific civil engineering environments are pursued. Copyright (c) 2006 John Wiley & Sons, Ltd.
引用
收藏
页码:649 / 659
页数:11
相关论文
共 50 条
  • [21] Diode Selection Strategies of RF Power Harvester to Improve Temperature Resilience of Battery-free Wireless Sensing
    Gu, Xiaoqiang
    Khazaka, Roni
    Wu, Ke
    PROCEEDINGS OF 2024 IEEE WIRELESS POWER TECHNOLOGY CONFERENCE AND EXPO, WPTCE, 2024, : 231 - 234
  • [22] Wireless sensing with power constraints
    Imer, Orhan C.
    Basar, Tamer
    ADVANCES IN CONTROL THEORY AND APPLICATIONS, 2007, 353 : 129 - +
  • [23] Minimize Power In Wireless Sensing
    Weiss, Joy
    Yu, Ross
    Simon, Jonathan
    MICROWAVES & RF, 2013, 52 (02) : 69 - 70
  • [24] Wireless Power Transfer using Magnetic Resonance Coupling for Neural Sensing Applications
    Yoon, Hargsoon
    Kim, Hyunjung
    Choi, Sang H.
    Sanford, Larry D.
    Geddis, Demetris
    Lee, Kunik
    Kim, Jaehwan
    Song, Kyo D.
    NANOSENSORS, BIOSENSORS, AND INFO-TECH SENSORS AND SYSTEMS 2012, 2012, 8344
  • [25] Standardized Low-Power Wireless Communication Technologies for Distributed Sensing Applications
    Vilajosana, Xavier
    Tuset-Peiro, Pere
    Vazquez-Gallego, Francisco
    Alonso-Zarate, Jesus
    Alonso, Luis
    SENSORS, 2014, 14 (02) : 2663 - 2682
  • [26] Performance evaluation and wireless sensing applications of an enhanced piezoelectric-electromagnetic hybrid energy harvester with bistable superposition mechanism
    Xu, Junjie
    Su, Xukun
    Zhu, Beining
    Qian, Nan
    Chen, Xiaoyu
    Wen, Xiangxiang
    Yang, Yubin
    Leng, Yonggang
    MECHANICAL SYSTEMS AND SIGNAL PROCESSING, 2025, 226
  • [27] An Integrated RF Energy Harvester for UHF Wireless Powering Applications
    Scorcioni, S.
    Larcher, L.
    Bertacchini, A.
    Vincetti, L.
    2013 IEEE WIRELESS POWER TRANSFER (WPT), 2013, : 92 - 95
  • [28] A multiple energy-harvester combination for pattern-recognizable power-free wireless sensing to vibration event
    He, Qisheng
    Dong, Chuan
    Li, Keli
    Wang, Jiachou
    Xu, Dacheng
    Li, Xinxin
    SENSORS AND ACTUATORS A-PHYSICAL, 2018, 279 : 229 - 239
  • [29] A wind energy harvester for low power Wireless Sensor Networks
    Ramasur, D.
    Hancke, G. P.
    2012 IEEE INTERNATIONAL INSTRUMENTATION AND MEASUREMENT TECHNOLOGY CONFERENCE (I2MTC), 2012, : 2623 - 2627
  • [30] Wireless power transfer system for a human motion energy harvester
    Pillatsch, Pit
    Yeatman, Eric M.
    Holmes, Andrew S.
    Wright, Paul K.
    SENSORS AND ACTUATORS A-PHYSICAL, 2016, 244 : 77 - 85
12345