感应和谐振无线电能传输技术的发展

doi:10.19595/j.cnki.1000-6753.tces.171305

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摘要

随着科技的不断发展和进步,无线电能传输技术已成为国内外最受关注的研究课题,是未来电力发展的必然趋势。首先介绍无线电能传输技术的起源,追溯到电磁波的发现;接着分析无线电能传输技术的三种主要形式,包括感应无线电能传输技术、谐振无线电能传输技术和微波无线电能传输技术。在此基础上,对三种形式的无线电能传输技术的发展现状进行论述,详细阐述目前国内外无线电能传输技术的研究成果,并对比分析目前研究最广泛的感应和谐振无线电能传输技术在原理、系统构成、分析方法以及运行条件上的异同,最后对无线电能传输技术在各个领域的应用进行了展望。

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	张波
	疏许健
	黄润鸿

关键词 ：感应, 谐振, 微波, 无线电能传输

Abstract：

With the continuous development of science and technology, wireless power transfer technology has become the most concerned research topic at home and abroad, and is the inevitable trend of future progress in power systems. In this paper, the origin of wireless power transfer technology is introduced, which traces back to the discovery of electromagnetic waves. Three main types of wireless power transfer technology are analyzed, including inductive wireless power transfer technology, resonant wireless power transfer technology and microwave wireless power transfer technology. On the basis of this, the development of three kinds of wireless power transfer technology is discussed, the research results of wireless power transfer technology are described in detail, and the similarities and differences between the most widely studied inductive and resonant wireless power transfer technology are analyzed. Finally, the application of wireless power transfer technology in various fields is prospected.

Key words： Inductive resonant microwave wireless power transfer

出版日期: 2017-10-10

PACS:

TM724

作者简介: 张波男,1962年生,教授,博士生导师,研究方向为电力电子与电力传动。E-mail: epbzhang@scut.edu.cn（通信作者）疏许健女,1993年生,硕士,研究方向为电力电子与电力传动。E-mail: epshuxujian@163.com

引用本文:

张波, 疏许健, 黄润鸿. 感应和谐振无线电能传输技术的发展[J]. 电工技术学报, 2017, 32(18): 3-17. Zhang Bo, Shu Xujian, Huang Runhong. The Development of Inductive and Resonant Wireless Power Transfer Technology. Transactions of China Electrotechnical Society, 2017, 32(18): 3-17.

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[1] Raabe S, Elliott G A J, Covic G A, et al. A quadrature pickup for inductive power transfer systems[C]// IEEE Industrial Electronics and Applications Conference, Harbin, China, 2007: 68-73.
[2] Kazmierkowski M P, Moradewicz A J. Contactless energy transfer (CET) systems-a review[C]//IEEE International Power Electronics and Motion Control Conference, Novi Sad, Serbia, 2012: 4-6.
[3] MIT Technology Review. 10 breakthrough tech- nologies. 2008.
[4] Marincic A S. Nikola Tesla and the wireless transmission of energy[J]. IEEE Transactions on Power Apparatus and Systems, 1982, 101(10): 4064- 4068.
[5] Tesla N. System of electric lighting: US, 454 622[P]. 1891-06-23.
[6] Barrett J P. Electricity at the Columbian expo- sition[M]. Madison: R R Donnelley, 1894.
[7] File: Tesla wireless power circuit.jpg[EB/OL]. https:// commons.wikimedia.org/wiki/File:Tesla_wireless_power_circuit.jpg.
[8] Tesla N. High frequency oscillators for electro- therapeutic and other purposes[J]. Proceedings of the IEEE, 1999, 87(7): 1282-1292.
[9] Tesla N. System of transmission of electrical energy: US, 645 576[P]. 1900-03-20.
[10] Hui S Y. Planar wireless charging technology for portable electronic products and Qi[J]. Proceedings of the IEEE, 2013, 101(6): 1290-1301.
[11] 野泽哲生, 蓬田宏树, 林咏. 伟大的电能无线传输技术[J]. 电子设计应用, 2007(6): 42-54.
Nozawa Tetsuo, Pengtian Hongshu, Lin Yong. Great power wireless transmission technology[J]. Elec- tronic Design and Application, 2007(6): 42-54.
[12] Hutin M, Leblanc M. Transformer system for electric railway: US, 527 857[P]. 1984-10-23.
[13] Kusserow B K. The use of a magnetic field to remotely power an implantable blood pump. Preli- minary report[J]. ASAIO Journal, 1960, 6(1): 292- 294.
[14] Schuder J C, Stephenson Jr H E, Townsend J F. Energy transfer into a closed chest by means of stationary coupling coils and a portable high-power oscillator[J]. ASAIO Journal, 1961, 7(1): 327-331.
[15] Schuder J C. Powering an artificial heart: birth of the inductively coupled-radio frequency system in 1960[J]. Artificial Organs, 2002, 26(11): 909-915.
[16] Schuder J C, Stephenson Jr H E, Townsend J F. High level electromagnetic energy transfer through a closed chest wall[C]//IRE International Convention Record 1961; 9: part 9,119-126.
[17] Schuder J C, Stephenson H E. Energy transport to a coil which circumscribes a ferrite core and is implanted within the body[J]. IEEE Transactions on Biomedical Engineering, 1965, (3, 4): 154-163.
[18] Thumim A I, Reed G E, Lupo F J, et al. High power electromagnetic energy transfer for totally implanted devices[J]. IEEE Transactions on Magnetics, 1970, 6(2): 326-332.
[19] John C Schuder, Jerry H Gold, Hugh E Stephenson. An inductively coupled RF system for the trans- mission of 1kW of power through the skin[J]. IEEE Transactions on Bio-Medical Engineering, 1971, BME-18(4): 265-273.
[20] Marx S H, Bounds R W. A kilowatt rotary power transformer[J]. IEEE Transactions on Aerospace and Electronic Systems, 1971, 7(6): 1157-1163.
[21] Roszyk L, Barnas L. Hand held battery operated device and charging means therefore: US, 3 840 795[P]. 1974-10.
[22] Bolger J G, Kirsten F A, Ng L S. Inductive power coupling for an electric highway system[C]//IEEE Proceedings of IEEE Vehicular Technology Con- ference, Denver, Colordo, USA, 1978: 137-144.
[23] Abel E, Third S. Contactless power transfer-an exercise in topology[J]. IEEE Transactions on Magnetics, 1984, 20(5): 1813-1815.
[24] Lashkari K, Shladover S E, Lechner E H. Inductive power transfer to an electric vehicle[C]//Proceedings of 8th International Electric Vehicle Symposium, Washington, DC, 1986: 258-267.
[25] Eghtesadi M. Inductive power transfer to an electric vehicle-analytical model[C]//Proceedings of IEEE 40th Vehicular Technology Conference, Orlando, FL, USA, 1990: 100-104.
[26] Ian C Foster. Theoretical design and implementation of a transcutaneous, multichannel stimulator for neural prosthesis applications[J]. Journal of Biomedical Engineering, 1981, 3(2): 107-120.
[27] Donaldson N N, Perkins T A. Analysis of resonant coupled coils in the design of radio frequency transcutaneous links[J]. Medical and Biological Engineering and Computing, 1983, 21(5): 612-627.
[28] Ghahary A, Cho B H. Design of a transcutaneous energy transmission system using a series resonant converter[C]//IEEE Power Electronics Specialists Conference, San Antonio, TX, USA, 2002: 1-8.
[29] Ghahary A, Cho B H. Design of transcutaneous energy transmission system using a series resonant converter[J]. IEEE Transactions on Power Elec- tronics, 1992, 7(2): 261-269.
[30] Joun G B, Cho B H. An energy transmission system for an artificial heart using leakage inductance compensation of transcutaneous transformer[C]// Proceedings of 27th Annual IEEE Power Electronics Specialist Conference, Baveno, 1996, 1(6): 898-904.
[31] Joun G B, Cho B H. An energy transmission system for an artificial heart using leakage inductance compensation of transcutaneous transformer[J]. IEEE Transactions on Power Electronics, 1998, 13(6): 1013-1022.
[32] Boys J T, Green A W. Inductive power distribution system: US, 5 293 308[P]. 1994-03-08.
[33] Green A W, Boys J T. 10 kHz inductively coupled power transfer-concept and control[C]//Proceedings of the 5th International Conference on Power Elec- tronics and Variable-Speed Drives, London, UK, 1994: 694-699.
[34] Elliott G A J, Boys J T, Green A W. Magnetically coupled systems for power transfer to electric vehicles[C]//Proceedings of the International Con- ference on Power Electronics and Drive Systems, Singapore, 1995, 2: 797-801.
[35] Boys J T, Covic G A, Green A W. Stability and control of inductively coupled power transfer systems[J]. IEEE Proceedings Electric Power Appli- cations, 2000, 147(1): 37-43.
[36] Chwei-Sen Wang, Stielau O H, Covic G A. Load models and their application in the design of loosely coupled inductive power transfer systems[C]// Proceedings of International Conference on Power System Technology, Perth, WA, Australia, 2000: 1053-1058.
[37] Chwei-Sen Wang, Covic G A, Stielau O H. General stability criterions for zero phase angle controlled loosely coupled inductive power transfer systems[C]// Proceedings of the 27th Annual Conference of the IEEE Industrial Electronics Society, Denver, CO, USA, 2001: 1049-1054.
[38] Splashpower. http://splashpower.com/
[39] Wild Charge. http://www.wildcharge.com/
[40] Hui S Y R, Wing W C Ho. A new generation of universal contactless battery charging platform for portable consumer electronic equipment[J]. IEEE Transactions on Power Electronics, 2005, 20(3): 620-627.
[41] Sekitani T, Takamiya M, Noguchi Y, et al. A large-area flexible wireless power transmission sheet using printed plastic MEMS switches and organic field-effect transistors[C]//Proceedings of IEEE International Electron Devices Meeting, San Francisco, CA, USA, 2006: 1-4.
[42] Sekitani T, Takamiya M, Noguchi Y, et al. A large-area wireless power-transmission sheet using printed organic transistors and plastic MEMS switches[J]. Nature Materials, 2007, 6(6): 413-417.
[43] 微软亚洲研究院. 无线供电桌面[EB/OL]. http://blog. sina.com.cn/s/ blog_4 caedc 7a01000aig.html
[44] 王洪博, 朱轶智, 杨军, 等. 无线供电技术的发展和应用前景[J]. 电信技术, 2010, 1(9): 56-59.
Wang Hongbo, Zhu Yizhi, Yang Jun, et al. The development and application prospect of wireless power supply technology[J]. Telecommunications Technology, 2010, 1(9): 56-59.
[45] Chwei-Sen Wang, Stielau O H, Covic G A, et al. Design considerations for a contactless electric vehicle battery charger[J]. IEEE Transactions on Industrial Electronics, 2005, 52(5): 1308-1314.
[46] Elliott G A J, Covic G A, Kacprzak D, et al. A new concept: asymmetrical pick-ups for inductively coupled power transfer monorail systems[J]. IEEE Transactions on Magnetics, 2006, 42(10): 3389-3391.
[47] Covic G A, Boys J T, Kissin M L G, et al. A three-phase inductive power transfer system for roadway-powered vehicles[J]. IEEE Transactions on Industrial Electronics, 2007, 54(6): 3370-3378.
[48] Budhia M, Covic G, Boys J. A new IPT magnetic coupler for electric vehicle charging systems[C]// Proceedings of the 36th Annual Conference on IEEE Industrial Electronics Society, Glendale, AZ, USA, 2010: 7-10.
[49] Chen L J, Tong W I S, Meyer B, et al. A contactless charging platform for swarm robots[C]//Proceedings of the 37th Annual Conference on IEEE Industrial Electronics Society, Melbourne, 2011: 7-10.
[50] Raval P, Kacprzak D, Hu A P. A wireless power transfer system for low power electronics charging applications[C]//Proceedings of the 6th IEEE Con- ference on Industrial Electronics and Applications, Beijing, 2011: 21-23.
[51] Budhia M, Boys J, Covic G, et al. Development of a single-sided flux magnetic coupler for electric vehicle IPT charging systems[J]. IEEE Transactions on Industrial Electronics, 2013, 60(1): 318-328.
[52] 李宏. 感应电能传输—电力电子及电气自动化的新领域[J]. 电气传动, 2001, 31(2): 62-64.
Li Hong. Inductive Power Transfer—a new field for power electronics and electric automation[J]. Elec- tric Drive, 2001, 31(2): 62-64.
[53] Wireless Power Consortium. Available: http://www. Wireless power consortium.com/cn
[54] Power Matters Alliance. Available: http: //www. Power matters. org/
[55] 戴欣, 孙跃. 单轨行车新型供电方式及相关技术分析[J]. 重庆大学学报, 2003, 26(1): 50-53.
Dai Xin, Sun Yue. Novel power supply method and technology analysis for electrified monorail system[J]. Journal of Chongqing University, 2003, 26(1): 50-53.
[56] Wu Ying, Yan Luguang, Xu Shangang. A new contactless power delivery system[C]//Proceedings of the Sixth Electrical Machines and Systems, Beijing, China, 2003, 1: 253-256.
[57] 武瑛, 严陆光, 黄常纲, 等. 新型非接触电能传输系统的性能分析[J]. 电工电能新技术, 2003, 22(4): 10-13.
Wu Ying, Yan Luguang, Huang Changgang, et al. Performance analysis of new contactless electrical energy transmission system[J]. Advanced Tech- nology of Electrical Engineering and Energy, 2003, 22(4): 10-13.
[58] 韩腾, 卓放, 王兆安. 采用非接触方式实现电能传输系统的研究[J]. 电气传动, 2004, 34(增刊1): 146-149.
Han Teng, Zhuo Fang, Wang Zhaoan. Study on a contactless power energy transfer system[J]. Electric Drive, 2004, 34(S1): 146-149.
[59] 武瑛, 严陆光, 徐善纲. 运动设备非接触供电系统耦合特性的研究[J]. 电工电能新技术, 2005, 24(3): 5-8.
Wu Ying, Yan Luguang, Xu Shangang. Study on coupling characteristics of contactless power supply system for moving apparatus[J]. Advanced Tech- nology of Electrical Engineering and Energy, 2005, 24(3): 5-8.
[60] 韩腾, 卓放, 闫军凯, 等. 非接触电能传输系统频率分叉现象研究[J]. 电工电能新技术, 2005, 24(2): 44-47.
Han Teng, Zhuo Fang, Yan Junkai, et al. Study of frequency bifurcation phenomenon of a contactless power transmission system[J]. Advanced Technology of Electrical Engineering and Energy, 2005, 24(2): 44-47.
[61] 盛松涛, 杜贵平, 张波. 感应耦合式非接触电能传输系统设计[J]. 通信电源技术, 2007, 24(5): 33-36.
Sheng Songtao, Du Guiping, Zhang Bo. The design of induction coupling no-touch power transfer system[J]. Telecom Power Technologies, 2007, 24(5): 33-36.
[62] 徐晔, 马皓. 串联补偿电压型非接触电能传输变换器的研究[J]. 电力电子技术, 2008, 42(3): 4-11.
Xu Ye, Ma Hao. Investigation on voltage source series resonant converter with series compensation for CEET[J]. Power Electronics, 2008, 42(3): 4-11.
[63] 杜贵平, 张波. 感应耦合式电能无线传输发展及其亟待解决的关键问题[J]. 国际电子变压器, 2009(4): 92-95.
Du Guiping, Zhang Bo. Wireless Transmission of electrical energy and the key problem[J]. Inter- national Electronic Transformer, 2008, 42(3): 4-11.
[64] 孙跃, 夏晨阳, 苏玉刚, 等. 导轨式非接触电能传输系统功率和效率的分析与优化[J]. 华南理工大学学报(自然科学版), 2010, 38(10): 123-129.
Sun Yue, Xia Chenyang, Su Yugang, et al. Analysis and optimization of transmission power and efficiency for rail-type contactless power transfer system[J]. Journal of South China University of Technology (Natural Science Edition), 2010, 38(10): 123-129.
[65] 沈爱民. 无线电能传输关键技术问题与应用前景(新视点新学说学术沙龙文集)[M]. 北京: 中国科学技术出版社, 2012.
[66] Kurs A, Karalis A, Moffatt R, et al. Wireless power transfer via strongly coupled magnetic resonances[J]. Science, 2007, 317(5834): 83-86.
[67] Imura T, Okabe H, Hori Y. Basic experimental study on helical antennas of wireless power transfer for electric vehicles by using magnetic resonant couplings[C]//Proceedings of IEEE Vehicle Power and Propulsion Conference, Dearborn, MI, USA, 2009: 936-940.
[68] Sedwick R J. Long range inductive power transfer with superconducting oscillators[J]. Annals of Physics, 2010, 325(2): 287-299.
[69] Sedwick R J. A fully analytic treatment of resonant inductive coupling in the far field[J]. Annals of Physics, 2012, 327(2): 407-420.
[70] Kurs Andre, Moffatt Robert, Soljacic Marin. Simultaneous mid-range power transfer to multiple devices[J]. Applied Physics Letters, 2010, 96(4): 044102-044102-3.
[71] Seung-Hwan Lee, Lorenz R D. Development and validation of model for 95% efficiency 220W wireless power transfer over a 30cm air gap[J]. IEEE Transactions on Industry Applications, 2011, 47(6): 2495-2504.
[72] Kim D W, Do Chung Y, Kang H K, et al. Characteristics of contactless power transfer for HTS coil based on electromagnetic resonance coupling[J]. IEEE Transactions on Applied Superconductivity, 2012, 22(3): 5400604.
[73] Kim D, Chung Y, Kang H, et al. Effects and properties of contactless power transfer for HTS receivers with four-separate resonance coils[J]. IEEE Transactions on Applied Superconductivity, 2013, 23(3): 5500404.
[74] Chen X Y, Jin J X. Resonant circuit and magnetic field analysis of superconducting contactless power transfer[C]//Proceedings of IEEE International Con- ference on Applied Superconductivity and Electro- magnetic Devices, Sydney, NSW, Australia, 2011: 5-8.
[75] 张波, 黄润鸿, 王学梅, 等. 采用超导线圈的谐振耦合无线输电系统及其实现方法: 中国CN201210503055.5[P]. 2012-11-30.
[76] Bait-Suwailam M M, Boybay M S, Ramahi O M. Electromagnetic coupling reduction in high-profile monopole antennas using single-negative magnetic metamaterials for MIMO applications[J]. IEEE Transactions on Antennas and Propagation, 2010, 58(9): 2894-2902.
[77] Urzhumov Y, Smith D R. Metamaterial-enhanced coupling between magnetic dipoles for efficient wireless power transfer[J]. Physical Review B, 2011, 83(20): 205114.
[78] Wang B, Teo K H, Nishino T, et al. Experiments on wireless power transfer with metamaterials[J]. Applied Physics Letters, 2011, 98(25): 254101- 254101-3.
[79] Liou C Y, Kuo C J, Lee M L, et al. Wireless charging system of mobile handset using metamaterial-based cavity resonator[C]//Proceedings of IEEE MTT-S International Microwave Symposium Digest, Montreal, 2012: 1-3.
[80] Wang B, Teo K H. Metamaterials for wireless power transfer[C]//Proceedings of IEEE International Work- shop on Antenna Technology, Tucson, AZ, 2012: 161-164.
[81] 新华网.海尔推出全球首台“无尾电视”[EB/OL]. http://news.xinhuanet.com/world/2010-01/08/content_ 12777268.htm.
[82] Alliance for Wireless Power. http://www. a4wp. org/
[83] Hu A P, Chao Liu, Hao Leo Li. A novel contactless battery charging system for soccer playing robot[C]// Proceedings of 15th International Conference on Mechatronics and Machine Vision in Practice, Auckland, New Zealand, 2008: 646-650.
[84] 胡友强, 戴欣. 基于电容耦合的非接触电能传输系统模型研究[J]. 仪器仪表学报, 2010, 31(9): 2133- 2139.
Hu Youqiang, Dai Xin. Study on modeling of capacitively coupled contactless power transfer system using generalized state space averaging method[J]. Chinese Journal of Scientific Instrument, 2010, 31(9): 2133-2139.
[85] Tsunekawa K. A feasibility study of wireless power transmission system by using two independent coupled electric fields[C]//Proceedings of IEEE MTT-S International Microwave Workshop Series on Innovative Wireless Power Transmission: Techno- logies, Systems, and Applications, Uji, Kyoto, Japan, 2011: 141-144.
[86] Leyh G E, Kennan M D. Efficient wireless transmission of power using resonators with coupled electric fields[C]//Proceedings of the 40th North American Power Symposium, Calgary, AB, Canada, 2008: 1-4.
[87] 傅文珍, 张波, 丘东元, 等. 自谐振线圈耦合式电能无线传输的最大效率分析与设计[J]. 中国电机工程学报, 2009, 29(18): 21-26.
Fu Wenzhen, Zhang Bo, Qiu Dongyuan, et al. Maximum efficiency analysis and design of self- resonance coupling coils for wireless power trans- mission system[J]. Proceeding of the CSEE, 2009, 29(18): 21-26.
[88] Zhu Chunbo, Yu Chunlai, Liu Kai, et al. Research on the topology of wireless energy transfer device[C]// Proceedings of IEEE Vehicle Power and Propulsion Conference, Harbin, 2008: 1-5.
[89] Zhu Chunbo, Liu Kai, Yu Chunlai, et al. Simulation and experimental analysis on wireless energy transfer based on magnetic resonances[C]//Proceedings of IEEE Vehicle Power and Propulsion Conference, Harbin, 2008: 1-4.
[90] 张献, 杨庆新, 陈海燕, 等. 电磁耦合谐振式无线电能传输系统的建模、设计与实验验证[J]. 中国电机工程学报, 2012, 32(21): 153-158.
Zhang Xian, Yang Qingxin, Chen Haiyan, et al. Modeling and design and experimental verification of contactless power transmission system via electro- magnetic resonant coupling[J]. Proceeding of the CSEE, 2012, 32(21): 153-158.
[91] 杨庆新, 陈海燕, 徐桂芝, 等. 无接触电能传输技术的研究进展[J]. 电工技术学报, 2010, 25(7): 6-13.
Yang Qingxin, Xu Haiyan, Xu Guizhi, et al. Research progress in contactless power transmission techno- logy[J]. Transactions of China Electrotechnical Society, 2010, 25(7): 6-13.
[92] 谭林林, 黄学良, 黄辉, 等. 基于频率控制的磁耦合共振式无线电力传输系统传输效率优化控制[J]. 中国科学: 技术科学, 2011, 41(7): 913-919.
Tan Linlin, Huang Xueliang, Huang Hui, et al. Trasfer efficiency optimal control of magnetic resonance coupled system of wireless power transfer based on frequency control[J]. Science China: Tech- nological Sciences, 2011, 41(7): 913-919.
[93] 翟渊, 孙跃, 戴欣, 等. 磁共振模式无线电能传输系统建模与分析[J]. 中国电机工程学报, 2012, 32(12): 155-160.
Zhai Yuan, Sun Yue, Dai Xin, et al. Modeling and analysis of magnetic resonance wireless power transmission systems[J]. Proceeding of the CSEE, 2012, 32(12): 155-160.
[94] 赵争鸣, 张艺明, 陈凯楠. 磁耦合谐振式无线电能传输技术新进展[J]. 中国电机工程学报, 2013, 33(3): 1-13.
Zhao Zhengming, Zhang Yiming, Chen Kainan. New progress of magnetically-coupled resonant wireless power transfer technology[J], Proceeding of the CSEE, 2013, 33(3): 1-13.
[95] Brown C W. The history of power transmission by radio waves[J]. IEEE Transactions on Microwave Theory and Techniques, 1984, 32(9): 1230-1242.
[96] Goubau G, Schwering F. On the guided propagation of electromagnetic wave beams[J]. IRE Transactions on Antennas and Propagation, 1961, AP-9(3): 248- 256.
[97] Glaser P E. Power from the sun: its future[J]. Science, 1968, 162(3856): 857-861.
[98] Dickinson R M. Performance of a high-power, 2.388GHz receiving array in wireless power transmission over 1.54km[C]//Proceedings of IEEE MTT-S International Microwave Symposium, Cherry Hill, NJ, USA, 1976: 139-141.
[99] Schlesak J, Alden A, Ohno T. SHARP rectenna and low altitude flight trials[C]//Proceedings of IEEE Global Telecommunication Conference, New Orleans, 1985: 960-964.
[100] Matsumoto H, Kaya N, Kimura I, et al. MINIX project toward the solar power satellite-rocket experiment of microwave energy transmission and associated nonlinear plasma physics in the ionosphere[C]//Proceedings of ISAS Space Energy Symposium, Japan, 1982: 69-76.
[101] Nagatomo M, Kaya N, Matsumoto H. Engineering aspect of the microwave ionosphere nonlinear interaction experiment (MINIX) with a sounding rocket[J]. Acta Astronaut, 1986, 13(1): 23-29.
[102] Fujino Y, Ito T, Fujita M, et al. A rectenna for MILAX[C]//Proceedings of First Wireless Power Transmission Conference, Japan, 1993: 273-277.
[103] Celeste A, Jeanty P, Pignolet G. Case study in Reunion island[J]. Acta Astronautica, 2004, 54(4): 253-258.
[104] Foust J. A step forward for space solar power[EB/OL]. 2008-09-15. http://www.thespace review.com/article/ 1210/1.
[105] Evans P. Solar power beamed from space within a decade?[EB/OL]. 2009-02-22. http://www.gizmag.com/ solar-power-space-satellite/ 1106/
[106] 林为干, 赵愉深, 文舸一, 等. 微波输电, 现代化建设的生力军[J]. 科技导报, 1994, 15(3): 31-34.
Lin Weigan, Zhao Yushen, Wen Geyi, et al. Power transmission by microwave, a propulsion for moder- nization construction[J], Science and Technology Review, 1994, 15(3): 31-34.
[107] 徐长龙, 徐君书, 徐得名. 管道探测微机器人微波输能系统激励装置[J]. 上海大学学报(自然科学版), 2000, 6(5): 403-406.
Xu Changlong, Xu Junshu, Xu Deming. The exciting device of microwave energy supply system for in- pipe inspect micro-machine[J]. Journal of Shanghai University(Natural Science), 2000, 6(5): 403-406.
[108] 候欣宾, 王立. 空间太阳能电站技术发展现状及展望[J]. 航天系统与技术(中国航天): 2015(2): 12-15.
Hou Xinbing, Wang Li. The present situation and prospect of the technology development of space solar power station[J]. Space System and Technology: 2015(2): 12-15.
[109] Yu C L, Lu R G, Mao Y H, et al. Research on the model of magnetic-resonance based wireless energy transfer system[C]//Proceedings of the 5th IEEE Vehicle Power and Propulsion Conference, Dearborn, MI, USA, 2009: 414-418.
[110] Sanghoon Cheon, Kim Y H, Kang S Y, et al. Circuit-model-based analysis of a wireless energy- transfer system via coupled magnetic resonances[J]. IEEE Transactions on Industry Electronics, 2011, 58(7): 2906-2914.
[111] Karalis A, Joannopoulos J D, Soljačić M. Efficient wireless non-radiative mid-range energy transfer[J]. Annals of Physics, 2008, 323(1): 34-48.
[112] Ho S L, Wang Junhua, Fu W N, et al. A comparative study between novel witricity and traditional inductive magnetic coupling in wireless charging[J]. IEEE Transactions on Magnetics, 2011, 47(5): 1522- 1525.