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A Review of Methods and Challenges for Improvement in Efficiency and Distance for Wireless Power Transfer Applications

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EN
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EN
Over the past few years, interest and research in wireless power transfer (WPT) have been rapidly incrementing, and as an effect, this is a remarkable technology in many electronic devices, electric vehicles and medical devices. However, most of the applications have been limited to very close distances because of efficiency concerns. Even though the inductive power transfer technique is becoming relatively mature, it has not shown near-field results more than a few metres away transmission. This review is focused on two fundamental aspects: the power efficiency and the transmission distance in WPT systems. Introducing the principles and the boundaries, scientific articles will be reviewed and discussed in terms of their methods and respective challenges. This paper also shows more important results in efficiency and distance obtained, clearly explaining the theory behind and obstacles to overcome. Furthermore, an overlook in other aspects and the latest research studies for this technology will be given. Moreover, new issues have been raised including safety and security.
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1--25
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Bibliogr. 170 poz., rys., tab.
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autor
  • The Department of Electrical Engineering and Electronics, University of Liverpool, 9 Brownlow Hill, Liverpool L69 3GJ, United Kingdom
autor
  • The Department of Electrical Engineering and Electronics, University of Liverpool, 9 Brownlow Hill, Liverpool L69 3GJ, United Kingdom
  • The Department of Electrical Engineering and Electronics, University of Liverpool, 9 Brownlow Hill, Liverpool L69 3GJ, United Kingdom
Bibliografia
  • Abou Houran, M., Yang, X. and Chen, W. (2018). Magnetically Coupled Resonance WPT: Review of Compensation Topologies, Resonator Structures with Misalignment, and EMI Diagnostics. Electronics, 7, p. 296.
  • Ahmad, A., Alam, M. S. and Chabaan, R. (2018). A Comprehensive Review of Wireless Charging Technologies for Electric Vehicles. IEEE Transaction on Transportation Electrification, 4, pp. 38–63.
  • Ahn, D. and Hong, S. (2013). Effects of Coupling between Multiple Transmitters or Multiple Receivers on Wireless Power Transfer. IEEE Transactions on Industrial Electronics, 60, pp. 2602–2613.
  • Ahn, D. and Hong, S. (2014). A Transmitter or a Receiver Consisting of Two Strongly Coupled Resonators for Enhanced Resonant Coupling in Wireless Power Transfer. IEEE Transactions on Industrial Electronics, 61, pp. 1193–1203.
  • Aldhaher, S., Luk, P. C. K. and Whidborne, J. F. (2014). Electronic Tuning of Misaligned Coils in Wireless Power Transfer Systems. IEEE Transactions on Power Electronics, 29, pp. 5975–5982.
  • Almasoud, A. H. and Gandayh, M. H. (2015). Future of Solar Energy in Saudi Arabia. Journal of King Saud University – Engineering Sciences, 27, pp. 153–157, 1018–3639.
  • Alphones, A. and Sampath, J. P. K. (2015). Metamaterial assisted wireless power transfer system. In: Proceedings of the Asia-Pacific Microwave Conference, pp. 1–3.
  • Balanis, C. A. (2005). Chapter 3. In Antenna Theory: Analysis and Design, 3rd ed. Hoboken, NJ: John Wiley & Sons, Inc.
  • Barman, S. D., Reza, A. W., Kumar, N., Karim, M. E. and Munir, A. B. (2015). Wireless Powering by Magnetic Resonant Coupling: Recent Trends in Wireless Power Transfer System and its Applications. Renewable and Sustainable Energy Reviews, 51, pp. 1525–1552.
  • Berger, A., Agostinelli, M., Vesti, S., Oliver, J. A., Cobos, J. A. and Huemer, M. (2015). A Wireless Charging System Applying Phase-Shift and Amplitude Control to Maximize Efficiency and Extractable Power. IEEE Transactions on Power Electronics, 30, pp. 6338–6348.
  • Besnoff, J., Chabalko, M. and Ricketts, D. S. (2016). A Frequency-Selective Zero-Permeability Metamaterial Shield for Reduction of Near-Field Electromagnetic Energy. IEEE Antennas and Wireless Propagation Letters, 15, pp. 654–657.
  • Bilotti, F. and Sevgi, L. (2012). Metamaterials: Definitions, Properties, Applications, and FDTD-Based Modeling and Simulation. International Journal of RF and Microwave Computer-Aided Engineering, 22, pp. 422–438.
  • Bosshard, R. and Kolar, J. W. (2016). Inductive Power Transfer for Electric Vehicle Charging: Technical Challenges And Tradeoffs. IEEE Power Electronics 3, pp. 22–30.
  • C.R Nave Georgia State University. (2001). Magnetic Properties of Ferromagnetic Materials. Retrieved 2013-12-01.
  • Cabrera, F. L. and De Sousa, F. R. (2016). Achieving Optimal Efficiency in Energy Transfer to a CMOS Fully Integrated Wireless Power Receiver. IEEE Transaction on Microwave Theory and Techniques, 64, pp. 3703–3713.
  • Campi, T., Cruciani, S., Palandrani, F., Santis, V. D., Hirata, A. and Feliziani, M. (2016). Wireless Power Transfer Charging System for AIMDs and Pacemakers. IEEE Transaction on Microwave Theory and Techniques, 64, pp. 633–642.
  • Campi, T., Cruciani, S., Santis, V. D., Maradei, F. and Feliziani, M. (2018). Feasibility study of a wireless power transfer system applied to a leadless pacemaker. IEEE Wireless Power Transfer Conference (WPTC), Montreal, QC, Canada: IEEE, pp. 1–4.
  • Cannon, B. L., Hoburg, J. F., Stancil, D. and Goldstein, S. C. (2009). Magnetic Resonant Coupling as a Potential Means for Wireless Power Transfer to Multiple Small Receivers. IEEE Transactions on Power Electronics, 24, pp. 1819–1825.
  • Casanova, J. J., Low, Z. N. and Lin, J. (2009). Design and Optimization of a Class-E Amplifier for a Loosely Coupled Planar Wireless Power System. IEEE Transactions on Circuits and Systems II: Express Briefs, 56, pp. 830–834.
  • Chabalko, M. J. and Sample, A. P. (2014). Resonant Cavity Mode Enabled Wireless Power Transfer. Applied Physics Letters, 105, p. 243902. AIP Publishing.
  • Chabalko, M. J. and Sample, A. P. (2015). Three-Dimensional Charging via Multimode Resonant Cavity Enabled Wireless Power Transfer. IEEE Transactions on Power Electronics, 30, pp. 6163–6173.
  • Charthad, J., Weber, M. J., Chang, T. C. and Arbabian, A. (2015). A mm-Sized Implantable Medical Device (IMD) with Ultrasonic Power Transfer and a Hybrid Bi-Directional Data Link. IEEE Journal of Solid-State Circuits, 50, pp. 1741–1753.
  • Chen, K. and Zhao, Z. (2013). Analysis of the Double-Layer Printed Spiral Coil for Wireless Power Transfer. IEEE Journal of Emerging and Selected Topics in Power Electronics, 1, pp. 114–121.
  • Chen, L., Liu, S., Zhou, Y. C. and Cui, T. J. (2013). An Optimizable Circuit Structure for High-Efficiency Wireless Power Transfer. IEEE Transactions on Industrial Electronics, 60, pp. 339–349.
  • Ching, T. W. and Wong, Y. S. (2013). Review of wireless charging technologies for electric vehicles. In: 5th International Conference on Power Electronics Systems and Applications (PESA), pp. 1–4.
  • Cho, Y., Kim, J. J., Kim, D. H., Lee, S., Kim, H., Song, C., et al. (2016). Thin PCB-Type Metamaterials for Improved Efficiency and Reduced EMF Leakage in Wireless Power Transfer Systems. IEEE Transaction on Microwave Theory and Techniques, 64, pp. 353–364.
  • Cho, Y., Lee, S., Kim, D. H., Kim, H., Song, C., Kong, S., et al. (2017). Thin Hybrid Metamaterial Slab with Negative and Zero Permeability for High Efficiency and Low Electromagnetic Field in Wireless Power Transfer Systems. IEEE Transactions on Electromagnetic Compatibility, 60, pp. 1001–1009.
  • Choi, B. H., Lee, E. S., Kim, J. H. and Rim, C. T. (2014a). 7m-off-long-distance extremely loosely coupled inductive power transfer systems using dipole coils. In: IEEE Energy. Conversion Congress and Expo (ECCE), pp. 858–563.
  • Choi, B. H., Lee, E. S., Sohn, Y. H., Jang, G. C. and Rim, C. T. (2016). Six Degrees of Freedom Mobile Inductive Power Transfer by Crossed Dipole Tx and Rx Coils. IEEE Transactions on Power Electronics, 31, pp. 3252–3272.
  • Choi, J. and Seo, C. H. (2010). High-Efficiency Wireless Energy Transmission Using Magnetic Resonance Based on Negative Refractive Index Metamaterial. Progress in Electromagnetics Research, 106, pp. 33–47.
  • Choi, J., Tsukiyama, D., Tsuruda, Y. and Davila, J. M. R. (2018). High-Frequency, High-Power Resonant Inverter with eGaN FET for Wireless Power Transfer. IEEE Transactions on Power Electronics, 33, pp. 1890–1896.
  • Choi, S. Y., Gu, B. W., Jeong, S. Y. and Rim, C. T. (2015). Advances in Wireless Power Transfer Systems for Roadway-Powered Electric Vehicles. IEEE Journal of Emerging and Selected Topics in Power Electronics, 3, pp. 18–36.
  • Choi, S. Y., Gu, B. W., Lee, S. W., Lee, W. Y., Huh, J. and Rim, C. T. (2014b). Generalized Active EMF Cancel Methods for Wireless Electric Vehicles. IEEE Transactions on Power Electronics, 29, pp. 5770–5783.
  • Cirimele, V., Freschi, F., Giaccone, L., Pichon, L. and Repetto, M. (2017). Human Exposure Assessment in Dynamic Inductive Power Transfer for Automotive Applications. IEEE Transactions on Magnetics, 53, pp. 1–4.
  • Cullity, B. D. and Graham, C. D. (2008). Introduction to Magnetic Materials, 2nd ed. p. 568, 16.
  • Dai, J. and Ludois, D. C. (2015). A Survey of Wireless Power Transfer and a Critical Comparison of Inductive and Capacitive Coupling for Small Gap Applications. IEEE Transactions on Power Electronics, 30, pp. 6017–6029.
  • Dai, X., Li, X., Li, Y. and Hu, P. (2018). Maximum Efficiency Tracking for Wireless Power Transfer Systems with Dynamic Coupling Coefficient Estimation. IEEE Transactions on Power Electronics, 33, pp. 5005–5015.
  • Deng, J., Li, W., Nguyen, T. D., Li, S. and Mi, C. C. (2015). Compact and Efficient Bipolar Coupler for Wireless Power Chargers: Design and Analysis. IEEE Transactions on Power Electronics, 30, pp. 6130–6140.
  • Deng, Q. J., Liu, J. T., Czarkowski, D., Hu, W. S. and Zhou, H. (2017). An Inductive Power Transfer System Supplied by a Multiphase Parallel Inverter. IEEE Transactions on Industrial Electronics, 64, pp. 7039–7048.
  • Diekhans, T. and Doncker, R. W. D. (2015). A Dual-Side Controlled Inductive Power Transfer System Optimized for Large Coupling Factor Variations and Partial Load. IEEE Transactions on Power Electronics, 30, pp. 6320–6328.
  • Elnail, K. E. I., Huang, X., Xiao, C., Tan, L. and Haozhe, X. (2018). Core Structure and Electromagnetic Field Evaluation in WPT Systems for Charging Electric Vehicles. Energies, 11, p. 1734.
  • Etemadrezaei, M. and Lukic, S. M. (2016). Coated-Strand Litz Wire For Multi-Megahertz Frequency Applications. IEEE Transactions on Magnetics, 52, pp. 1–11.
  • Fakidis, J., Videv, S., Kucera, S., Claussen, H. and Haas, H. (2016). Indoor Optical Wireless Power Transfer to Small Cells at Nighttime. Journal of Lightwave Technology, 34, pp. 3236–3258.
  • Feng, H., Cai, T., Duan, S., Zhao, J., Zhang, X. and Chen, C. (2016). An LCC Compensated Resonant Converter Optimized for Robust Reaction to Large Coupling Variation in Dynamic Wireless Power Transfer. IEEE Transactions on Industrial Electronics, 63, pp. 6591–6601.
  • Fu, M., Ma, C. and Zhu, X. (2014). A Cascaded Boost-Buck Converter for High Efficiency Wireless Power Transfer Systems. IEEE Transactions on Industrial Informatics, 10, pp. 1972–1980.
  • Galbraith, D. C., Soma, M. and White, R. L. (1987). A Wide-Band Efficient Inductive Transdennal Power and Data Link with Coupling Insensitive Gain. IEEE Transactions on Biomedical Engineering, 34, pp. 265–275.
  • Garnica, J., Chinga, R. A. and Lin, J. (2013). Wireless Power Transmission: From Far Field to Near Field. Proceedings of the IEEE, 101, pp. 1321–1331.
  • Grover, F. W. (2004). Inductance Calculations: Working Formulas and Tables. Washington, DC, USA: Courier Corporation.
  • Hadadtehrani, P., Kamalinejad, P., Molavi, R. and Mirabbasi, S. (2016). On the use of conical helix inductors in wireless power transfer systems. In: Proceedings of the IEEE Canadian Conference on Electrical and Computer Engineering (CCECE), pp. 1–4.
  • Hao, H., Covic, G. A. and Boys, J. T. (2014). A Parallel Topology for Inductive Power Transfer Power Supplies. IEEE Transactions on Power Electronics, 29, pp. 1140–1151.
  • Health Physics International Commission on Non-Ionizing Radiation Protection. (2010). Guidelines for Limiting Exposure to Time-Varying Electric and Magnetic Fields (1Hz to 100kHz). 99, pp. 818–836.
  • Ho, J. S., Kim, S. and Poon, A. S. Y. (2013). Midfield Wireless Powering for Implantable Systems. Proceedings of the IEEE, 101, pp. 1369–1378.
  • Hoang, H. and Bien, F. (2012). Maximizing Efficiency of Electromagnetic Resonance Wireless Power Transmission Systems with Adaptive Circuits. InTech Open Access, pp. 207–225.
  • Holmer, N. G. and Lindstrom, K. (1973). Highly Isolated Power Supply Energized by Ultrasound. Journal of Medical and Biological Engineering, 11, pp. 233–235.
  • Hou, J., Chen, Q., Wong, S. C., Tse, C. K. and Ruan, X. (2015). Analysis and Control of Series/Series-Parallel Compensated Resonant Converter for Contactless Power Transfer. IEEE Journal of Emerging and Selected Topics in Power Electronics, 3, pp. 124–136.
  • Huh, J., Lee, S. W., Lee, W. Y., Cho, G. H. and Rim, C. T. (2011). Narrow-Width Inductive Power Transfer System for Online Electrical Vehicles. IEEE Transactions on Power Electronics, 26, pp. 3666–3679.
  • Hui, S. Y. R., Zhong, W. and Lee, C. K. (2014). A Critical Review of Recent Progress in Mid-Range Wireless Power Transfer. IEEE Transactions on Power Electronics, 9, pp. 4500–4511.
  • Hwang, K., Cho, J., Kim, D., Park, J., Kwon, J. K., Kwak, S. I., et al. (2014). An Autonomous Coil Alignment System for the Dynamic Wireless Charging of Electric Vehicles to Minimize Lateral Misalignment. Energies, 10, p. 315.
  • Jarvis, S., Mukherjee, J., Perren, M. and Sweeney, J. S. (2013). On the fundamental efficiency limits of photovoltaic converters for optical power transfer applications. 39th IEEE Photovoltaic Specialists Conference (PVSC), IEEE, pp. 1031–1035.
  • Jawad, A. M., Nordin, R. G., Sadik, K., Jawad, H. M., Ismail, M. and Abu-AlShaeer, M. J. (2018). Single-Tube and Multi-Turn Coil Near-Field Wireless Power Transfer for Low-Power Home Appliances. Energies, 11, p. 1969.
  • Jeong, I. S., Jung, B. I., You, D. S. and Choi, H. S. (2016). Analysis of S-Parameters in Magnetic Resonance WPT Using Superconducting Coils. IEEE Transactions on Applied Superconductivity, 26, pp. 1–4.
  • Jiang, C., Chau, K. T., Ching, T. W., Liu, C. and Han, W. (2017b). Time-Division Multiplexing Wireless Power Transfer for Separately Excited DC Motor Drives. IEEE Transactions on Magnetics, 53, pp. 1–5.
  • Jiang, C., Chau, K. T., Liu, C. and Lee, C. H. T. (2017a). An Overview of Resonant Circuits for Wireless Power Transfer. Energies, 10, p. 894.
  • Jo, M., Sato, Y., Kaneko, Y. and Abe, S. (2014). Methods for reducing leakage electric field of a wireless power transfer system for electric vehicles. In: Proceedings of the IEEE Energy Conversion Congress and Exposition (ECCE), pp. 1762–1769.
  • Jolani, F., Yu, Y. and Chen, Z. (2014). A Planar Magnetically Coupled Resonant Wireless Power Transfer System Using Printed Spiral Coils. IEEE Antennas and Wireless Propagation Letters, 13, pp. 1648–1651.
  • Jonah, O., Georgakopoulos, S. V. and Tentzeris, M. M. (2013). Orientation insensitive power transfer by magnetic resonance for mobile devices. In: IEEE Wireless Power Transfer, pp. 5–8.
  • Kan, T., Nguyen, T. D., White, J. C., Malhan, R. K. and Mi, C. C. (2017). A New Integration Method for an Electric Vehicle Wireless Charging System Using LCC Compensation Topology: Analysis and Design. IEEE Transactions on Power Electronics, 32, pp. 1638–1650.
  • Kazmierkowski, M. P. and Moradewicz, A. J. (2012). Unplugged but Connected: Review of Contactless Energy Transfer Systems. IEEE Industrial Electronics Magazine, 6, pp. 47–55.
  • Khan, I., Qureshi, M. I., Rehman, M. U. and Khan, W. T. (2017). Long range wireless power transfer via magnetic resonance. In: Progress in Electromagnetics Research Symposium - Fall (PIERS - FALL), pp. 3079–3085.
  • Kim, D., Abu-Siada, A. and Sutinjo, A. (2018). State-of-the-Art Literature Review of WPT: Current Limitations and Solutions on IPT. Electric Power Systems Research, 154, pp. 493–502, 0378–7796.
  • Kim, J., Kim, H., Song, C., Kim, I. M., Kim, Y. and Kim, J. (2014). Electromagnetic interference and radiation from wireless power transfer systems. In: Proceedings of the International Symposium on Electromagnetic Compatibility (EMC), pp. 171–176.
  • Kim, K. Y. (2009). Comparative Analysis of Guided Modal Properties of Double Positive and Double-Negative Meta-Material Slab Waveguides. Radio Engineering, 18, pp. 17–123.
  • Kim, M., Kim, H., Kim, D., Jeong, Y., Park, H. H. and Ahn, S. (2015a). A Three-Phase Wireless-Power-Transfer System for Online Electric Vehicles with Reduction of Leakage Magnetic Fields. IEEE Transactions on Microwave Theory and Techniques, 63, pp. 3806–3813.
  • Kim, S., Jung, D. H., Kim, J. J., Bae, B., Kong, S., Ahn, S., et al. (2015b). High-Efficiency PCB-and Package-Level Wireless Power Transfer Interconnection Scheme Using Magnetic Field Resonance Coupling. IEEE Transactions on Components, Packaging and Manufacturing Technology, 5, pp. 863–878.
  • Kim, Y. H., Kang, S. Y., Cheon, S., Lee, M. L. and Zyung, T. (2010). Wireless power transmission to multi devices through resonant coupling. Proceedings of the International Conference on Electronics Machine System, pp. 2000–2002.
  • Kimmich, H. P. (1982). Biotelemetry, Based on Optical Transmission. Biotelemetry and Patient Monitoring, 9, pp. 129–143.
  • Ko, Y. D. and Jang, Y. J. (2013). The Optimal System Design of the Online Electric Vehicle Utilizing Wireless Power Transmission Technology. IEEE Transactions on Intelligent Transportation Systems, 2013, pp. 1255–1265.
  • Koohestani, M., Zhadobov, M. and Ettorre, M. (2017). Design Methodology of a Printed WPT System for HF-Band Mid-Range Applications Considering Human Safety Regulations. IEEE Transactions on Microwave Theory and Techniques, 65, pp. 270–279.
  • Kurs, A., Karalis, A., Moffatt, R., Joannopoulos, J. D., Fisher, P. and Soljacic, M. (2007). Wireless Power Transfer via Strongly Coupled Magnetic Resonances. Science, 317, pp. 83–86.
  • Kurs, A., Moffatt, R. and Solijacic, M. (2010). Simultaneous Mid-Range Power Transfer to Multiple Devices. Applied Physics Letters, 96, p. 044102. American Institute of Physics (AIP)
  • Laakso, I., Hirata, A. and Fujiwara, O. (2014). Computational dosimetry for wireless charging of an electrical vehicle. In: Proceedings of the International Symposium on Electromagnetic, pp. 202–205.
  • Lee, B., Yeon, P. and Ghovanloo, M. (2016b). A Multi-Cycle Q-Modulation for Dynamic Optimization of Inductive Links. IEEE Transactions on Industrial Electronics, 63, pp. 5091–5100.
  • Lee, K. and Cho, D. H. (2013). Diversity Analysis of Multiple Transmitters in Wireless Power Transfer System. IEEE Transactions on Magnetics, 49, pp. 2946–2952.
  • Lee, S. H. and Lorenz, R. D. (2013). Surface spiral coil design methodologies for high efficiency high power low flux density large air-gap wireless power transfer systems. In: IEEE Applied Power Electronics Conference and Expo (APEC), pp. 1783–1790.
  • Lee, S. H., Lee, B. S. and Lee, J. H. (2016a). A New Design Methodology for a 300-kW, Low Flux Density, Large Air Gap, Online Wireless Power Transfer System. IEEE Transactions on Industry Applications, 52, pp. 4234–4242.
  • Lee, W. S., Son, W. I., Oh, K. S. and Yu, J. W. (2015). Contactless Energy Transfer Systems Using Antiparallel Resonant Loops. IEEE Transactions on Industrial Electronics, 60, pp. 350–359.
  • Li, H. C., Li, J., Wang, K. P., Chen, W. J. and Yang, X. (2015b). A Maximum Efficiency Point Tracking Control Scheme for Wireless Power Transfer Systems Using Magnetic Resonant Coupling. IEEE Transactions on Power Electronics, 30, pp. 3998–4008.
  • Li, H., Fang, J., Chen, S., Wang, K. and Tang, Y. (2018). Pulse Density Modulation for Maximum Efficiency Point Tracking of Wireless Power Transfer Systems. IEEE Transactions on Power Electronics, 33, pp. 5492–5501.
  • Li, S., Li, W., Deng, J., Nguyen, T. D. and Mi, C. C. (2014). A Double-Sided LCC Compensation Network and its Tuning Method for Wireless Power Transfer. IEEE Transactions on Vehicular Technology, 64, pp. 2261–2273.
  • Li, W., Zhao, H., Deng, J., Li, S. and Mi, C. C. (2016). Comparison Study on SS and Double-Sided LCC Compensation Topologies for EV/PHEV Wireless Chargers. IEEE Transactions on Vehicular Technology, 65, pp. 4429–4439.
  • Li, W., Zhao, H., Li, S., Deng, J., Kan, T. and Mi, C. C. (2015a). Integrated LCC Compensation Topology for Wireless Charger in Electric and Plug-in Electric Vehicles. IEEE Transactions on Industrial Electronics, 62, pp. 4215–4225.
  • Lim, Y., Tang, H., Lim, S. and Park, J. (2014). An Adaptive Impedance-Matching Network Based on a Novel Capacitor Matrix for Wireless Power Transfer. IEEE Transactions on Power Electronics, 29, pp. 4403–4413.
  • Liu, F., Zhang, Y., Chen, K., Zhao, Z. and Yuan, L. (2016). A comparative study of load characteristics of resonance types in wireless transmission systems. In: Proceedings on the IEEE Asia-Pacific International Symposium on Electromagnetic, Vol. 1, pp. 203–206.
  • Liu, Y., Li, B., Huang, M., Chen, Z. and Zhang, X. (2018). An Overview of Regulation Topologies in Resonant Wireless Power Transfer Systems for Consumer Electronics or Bio-Implants. Energies, 11, p. 1737.
  • Low, Z. N., Chinga, R. A., Tseng, R. and Lin, J. (2009). Design and Test of a High-Power High-Efficiency Loosely Coupled Planar Wireless Power Transfer System. IEEE Transactions on Industrial Electronics, 56, pp. 1801–1812.
  • Lu, F., Zhang, H., Hofmann, H. and Mi, C. C. (2016). A Dynamic Charging System with Reduced Output Power Pulsation for Electric Vehicles. IEEE Transactions on Industrial Electronics, 63, pp. 6580–6590.
  • Madawala, U. K. and Thrimawithana, D. J. (2011). A Bidirectional Inductive Power Interface for Electric Vehicles in V2G Systems. IEEE Transactions on Industrial Electronics, 58, pp. 4789–4796.
  • Mai, R. K., Liu, Y. R., Li, Y., Yue, P. F., Cao, G. Z. and He, Z. Y. (2018). An Active Rectifier-Based Maximum Efficiency Tracking Method Using an Additional Measurement Coil for Wireless Power Transfer. IEEE Transactions on Power Electronics, 33, pp. 716–728.
  • Marian, V., Allard, B., Vollaire, C. and Verdier, J. (2012). Strategy for Microwave Energy Harvesting from Ambient Field or a Feeding Source. IEEE Transactions on Power Electronics, 27, pp. 4481–4491.
  • Market Research Future. (2019). Wireless Power Transmission Market 2019 Global Industry Size, Growth, Emerging Technologies, Competitive Landscape, Opportunities, Segmentation, Future Trends and Regional Forecast 2022. Global Wireless Power Transmission Market Research Report- Forecast 2022 Market Analysis, Scope, Stake, Progress, Trends and Forecast to 2022. Available at: https://www.marketwatch.com/press-release/wireless-power-transmission-market-2019-global-industry-size-growth-emerging-technologies-competitive-landscape-opportunities-segmentation-future-trends-and-regional-forecast-2022-2019-03-12 [Accessed 3 Sept 2019].
  • Markets and Markets. (2019). Market Research Report. Available at: https://www.marketsandmarkets.com/PressReleases/wireless-power-transmission.asp [Accessed 13 Jan 2019]
  • Mei, H., Huang, Y. W., Thackston, K. A. and Irazoqui, P. P. (2016). Optimal Wireless Power Transfer to Systems in an Enclosed Resonant Cavity. IEEE Antennas and Wireless Propagation Letters, 15, pp. 1036–1039.
  • Mei, H., Thackston, K. A., Bercich, R. A., Jefferys, J. G. and Irazoqui, P. P. (2017). Cavity Resonator Wireless Power Transfer System for Freely Moving Animal Experiments. IEEE Transactions on Biomedical Engineering, 64, pp. 775–785.
  • Miller, J. M., Onar, O. C. and Chinthavali, M. (2015). Primary-Side Power Flow Control of Wireless Power Transfer for Electric Vehicle Charging. IEEE Journal of Emerging and Selected Topics in Power Electronics, 3, pp. 147–162.
  • Mirbozorgi, S. A., Yeon, P. and Ghovanloo, M. (2017). Robust Wireless Power Transmission to mm-Sized Free-Floating Distributed Implants. IEEE Transactions on Biomedical Circuits and Systems, 11, pp. 692–702.
  • Mohan, S. S. (1999). The Design, Modeling and Optimization of On-Chip Inductor and Transformer Circuits. Ph.D. Thesis. Stanford, CA, USA: Stanford University.
  • Moon, S. and Moon, G. W. (2016). Wireless Power Transfer System with an Asymmetric Four-Coil Resonator for Electric Vehicle Battery Chargers. IEEE Transactions on Power Electronics, 31, pp. 6844–6854.
  • Mur-Miranda, J. O., Fanti, G., Feng, Y., Omanakuttan, K., Ongie, R., Setjoadi, A., et al. (2010). Wireless power transfer using weakly coupled magneto-static resonators. In: Proceedings of the IEEE ECCE, pp. 4179–4186.
  • Musavi, F. and Eberle, W. (2014). Overview of Wireless Power Transfer Technologies for Electric Vehicle Battery Charging. IET Power Electronics, 7, pp. 60–66.
  • Nguyen, V. T., Yu, S., Yim, S. and Park, K. (2017). Optimizing compensation topologies for inductive power transfer at different mutual inductances. In: IEEE PELS Workshop on Emerging Technologies: Wireless Power Transmission (WoW), pp. 153–156.
  • Oh, T. and Lee, B. (2013). Analysis of Wireless Power Transfer Using Metamaterial Slabs Made of Ring Resonators at 13.56 MHz. Journal of Electromagnetic Engineering and Science, 13, pp. 259–262.
  • Onar, O. C., Miller, J. M., Campbell, S. L., Coomer, C., White, C. P. and Seiber, L. E. (2013). A novel wireless power transfer for in-motion EV/PHEV charging. In: Proceedings of the IEEE Applied Power Electronics Conference Exposition (APEC), pp. 3073–3080.
  • Park, C., Lee, S., Cho, G. H. and Rim, C. T. (2015). Innovative 5-m-Off-Distance Inductive Power Transfer Systems with Optimally Shaped Dipole Coils. IEEE Transactions on Power Electronics, 30, pp. 817–827.
  • Park, J., Tak, Y., Kim, Y., Kim, Y. and Nam, S. (2011). Investigation of Adaptive Matching Methods for Near-Field Wireless Power Transfer. IEEE Transactions on Antennas and Propagation, 59, pp. 1769–1773.
  • Park, M., Nguyen, V. T., Yu, S. D., Yim, S. W., Park, K., Min, B. D., et al. (2016). A study of wireless power transfer topologies for 3.3 kW and 6.6 kW electric vehicle charging infrastructure. In: Proceedings of the IEEE Transportation Electrification Conference and Expo (ITEC Asia-Pacific), pp. 689–692.
  • Patil, D., McDonough, M. K., Miller, J. M., Fahimi, B. and Balsara, P. T. (2018). Wireless Power Transfer for Vehicular Applications: Overview and Challenges. IEEE Transactions on Transportation Electrification, 4, pp. 3–37.
  • Pinuela, M., Yates, D. C., Lucyszyn, S. and Mitcheson, P. D. (2013). Maximizing DC-to-Load Efficiency for Inductive Power Transfer. IEEE Transactions on Power Electronics, 28, pp. 2437–2447.
  • Qu, X., Jing, Y., Han, H., Wong, S. C. and Tse, C. K. (2017). Higher Order Compensation for Inductive-Power-Transfer Converters with Constant-Voltage or Constant-Current Output Combating Transformer Parameter Constraints. IEEE Transactions on Power Electronics, 32, pp. 394–405.
  • Raab, F. H. (1978). Effects of Circuit Variations on the Class E Tuned Power Amplifier. IEEE Journal of Solid-State Circuits, 13, pp. 239–247.
  • RamRakhyani, A. K. and Lazzi, G. (2013). On the Design of Efficient Multi-Coil Telemetry System for Biomedical Implants. IEEE Transactions on Biomedical Circuits and Systems, 7, p. 11.
  • Ranaweera, A., Duong, T. P., Lee, B. S. and Lee, J. K. (2014). Experimental investigation of 3D metamaterial formid-range wireless power transfer. In: Proceedings of the IEEE Wireless Power Transfer Conference, pp. 92–95.
  • Reatti, A., Corti, F. and Pugi, L. (2018). Wireless power transfer for static railway applications. In: IEEE International Conference on Environment and Electrical Engineering/IEEE Industrial and Commercial Power System Europe (EEEIC/I&CPS Europe), pp. 1–6.
  • Relative Permeability Hyperphysics. (2008). Hyperphysics.phy-astr.gsu.edu. Retrieved 2011-11-08.
  • Samanta, S. and Rathore, A. K. (2015). A New Current-Fed CLC Transmitter and LC Receiver Topology for Inductive Wireless Power Transfer Application: Analysis, Design, and Experimental Results. IEEE Transactions on Transportation Electrification, 1, pp. 357–368.
  • Sample, A. P., Meyer, D. T. and Smith, J. R. (2011). Analysis, Experimental Results, and Range Adaptation of Magnetically Coupled Resonators for Wireless Power Transfer. IEEE Transactions on Industrial Electronics, 58, pp. 544–554.
  • Sandoval, F. S., Delgado, S. M., Moazenzadeh, A. and Wallrabe, U. (2017). Nulls-Free Wireless Power Transfer with Straightforward Control of Magneto Inductive Waves. IEEE Transactions on Microwave Theory and Techniques, 65, pp. 1087–1093.
  • Sato, M., Yamamoto, G., Gunji, D., Imura, T. and Fujimoto, H. (2016). Development of Wireless In-Wheel Motor Using Magnetic Resonance Coupling. IEEE Transactions on Power Electronics, 31, pp. 5270–5278.
  • Seo, D. W., Lee, J. H. and Lee, H. S. (2016). Optimal Coupling to Achieve Maximum Output Power in a WPT System. IEEE Transactions on Industrial Electronics, 31, pp. 3994–3998.
  • Shekhar, A., Prasanth, V., Bauer, P. and Bolech, M. (2016). Economic Viability Study of an On-Road Wireless Charging System with a Generic Driving Range Estimation Method. Energies, 9, p. 76.
  • Shin, J., Shin, S., Kim, Y., Ahn, S., Lee, S., Jung, G., et al. (2014). Design and Implementation of Shaped Magnetic-Resonance-Based Wireless Power Transfer System for Roadway-Powered Moving Electric Vehicles. IEEE Transactions on Industrial Electronics, 61, pp. 1179–1192.
  • Sokal, N. O. (1998). Class E High-Efficiency Power Amplifiers, from HF to Microwave. IEEE MTT-S International Microwave Symposium Digest, 2, pp. 1109–1112.
  • Sokal, N. O. and Sokal, A. D. (1975). Class E-A New Class of High-Efficiency Tuned Single-Ended Switching Power Amplifiers. IEEE Journal of Solid-State Circuits, 10, pp. 168–176.
  • Song, J., Kim, S., Bae, B., Kim, J. J., Jung, D. H. and Kim, J. (2014). Design and analysis of magnetically coupled coil structures for PCB-to-active interposer wireless power transfer in 2.5 D/3D- IC. In: Proceedings of the IEEE Electrical Design of Advanced Packaging and System Symposium (EDAPS), pp. 1–4.
  • Sullivan, C. R. (2013). Layered foil as an alternative to Litz wire: multiple methods for equal current sharing among layers. In: Workshop on Control and Modeling for Power Electronics (COMPEL).
  • Tampubolon, M., Pamungkas, L., Chiu, H. J., Liu, Y. C. and Hsieh, Y. C. (2018). Dynamic Wireless Power Transfer for Logistic Robots. Energies, 11, p. 527.
  • Theodoridis, M. P. (2012). Effective Capacitive Power Transfer. IEEE Transactions on Power Electronics, 27, pp. 4906–4913.
  • Thompson, M. C. (1991). Inductance Calculation Techniques-Part II: Approximations and Handbook Methods. University Park, PA, USA: CiteSeer.
  • Trung, N. K., Ogata, T., Tanaka, S. and Akatsu, K. (2015). PCB design for 13.56MHz half-bridge class D inverter for wireless power transfer system. 9th International Conference on Power Electronics – ECCE Asia (ICPE-ECCE Asia), pp. 1692–1699.
  • Tsuji, T., Fujimoto, T., Izuto, T. and Togawa, T. (1993). Telemetry of organ temperature with quartz crystal resonator using ultrasonic detection for preoperative patient monitoring. Proceedings of the 12th International Symposium Biotel, IEEE, pp. 378–380.
  • Umenei, A. E. (2019). Understanding Low Frequency Non-Radiative Power Transfer. Available at: https://www.wirelesspowerconsortium.com [Accessed 13 Jan 2019].
  • Villa, J. L., Sallan, J., Osorio, J. F. S. and Llombart, A. (2012). High-Misalignment Tolerant Compensation Topology for ICPT Systems. IEEE Transactions on Industrial Electronics, 59, pp. 945–951.
  • Wang, B. and Teo, K. H. (2012). Metamaterials for wireless power transfer. Proceedings of the IEEE International Workshop Antenna Technology, pp. 161–164.
  • Wang, C. S., Covic, G. A. and Stielau, O. H. (2004). Investigating an LCL Load Resonant Inverter for Inductive Power Transfer Applications. IEEE Transactions on Power Electronics, 19, pp. 995–1002.
  • Wang, C. S., Stielau, O. H. and Covic, G. A. (2005). Design Considerations for a Contactless Electric Vehicle Battery Charger. IEEE Transactions on Industrial Electronics, 52, pp. 1308–1314.
  • Wang, Y. F., Yang, L., Wang, C. S., Li, W., Qie, W. and Tu, S. J. (2015). High Step-Up 3-Phase Rectifier with Fly-Back Cells and Switched Capacitors for Small-Scaled Wind Generation Systems. Energies, 8, pp. 2742–2768.
  • Wang, Y., Yao, Y., Liu, X. and Xu, D. (2017). S/CLC Compensation Topology Analysis and Circular Coil Design for Wireless Power Transfer. IEEE Transactions on Transportation Electrification, 3, pp. 496–507.
  • Wang, Z., Wei, X. and Dai, H. (2016). Design and Control of a 3 kW Wireless Power Transfer System for Electric Vehicles. Energies, 9, p. 10.
  • Wei, X., Wang, Z. and Dai, H. (2014). A Critical Review of Wireless Power Transfer via Strongly Coupled Magnetic Resonances. Energies, 7(7), pp. 4316–4341.
  • Wen, F. and Huang, X. (2016). Optimal Magnetic Field Shielding Method by Metallic Sheets in Wireless Power Transfer System. Energies, 9, p. 733.
  • Wu, H. H., Gilchrist, A., Sealy, K. and Bronson, D. (2012a). A 90 percent efficient 5 kW inductive charger for EVs. In: Proceedings of IEEE Energy Conversion Congress and Exposition, pp. 275–282.
  • Wu, H. H., Gilchrist, A., Sealy, K. D. and Bronson, D. (2012b). A High Efficiency 5 kW Inductive Charger for EVs Using Dual Side Control. IEEE Transactions on Industrial Informatics, 8, pp. 585–595.
  • Wu, J., Wang, B., Yerazunis, W. S. and Teo, K. H. (2013). Wireless power transfer with artificial magnetic conductors. In: Proceedings of the IEEE Wireless Power Transmission Conference, pp. 155–158.
  • Yang, C. and Tsunekawa, K. (2014). A novel parallel double helix loop resonator for magnetic coupled resonance wireless power transfer. In: PIERS Proceedings, pp. 466–470.
  • Yang, Y., El Baghdadi, M., Lan, Y., Benomar, Y., Van Mierlo, J. and Hegazy, O. (2018). Design Methodology, Modeling, and Comparative Study of Wireless Power Transfer Systems for Electric Vehicles. Energies, 11, p. 1716.
  • Yeo, T. D., Kwon, D., Khang, S. T. and Yu, J. W. (2017). Design of Maximum Efficiency Tracking Control Scheme for Closed-Loop Wireless Power Charging System Employing Series Resonant Tank. IEEE Transactions on Power Electronics, 32, pp. 471–478.
  • Yi, Y., Buttner, U., Fan, Y. and Foulds, I. G. (2015). Design and Optimization of a 3-Coil Resonance-Based Wireless Power Transfer System for Biomedical Implants. International Journal of Circuit Theory and Applications, 43, pp. 1379–1390.
  • Yoon, I. J. and Ling, H. (2011). Investigation of Near-Field Wireless Power Transfer under Multiple Transmitters. IEEE Antennas and Wireless Propagation Letters, 10, pp. 662–665.
  • Zhang, F., Liu, J., Mao, Z. and Sun, M. (2012). Mid-Range Wireless Power Transfer and its Application to Body Sensor Networks. Open Journal of Applied Sciences, 2, pp. 35–46.
  • Zhang, H., Lu, F., Hofmann, H., Liu, W. and Mi, C. C. (2016). A Four-Plate Compact Capacitive Coupler Design and LCL-Compensated Topology for Capacitive Power Transfer in Electric Vehicle Charging Application. IEEE Transactions on Power Electronics, 31, pp. 8541–8551.
  • Zhang, J., Yuan, X., Wang, C. and He, Y. (2017). Comparative Analysis of Two-Coil and Three-Coil Structures for Wireless Power Transfer. IEEE Transactions on Power Electronics, 32, pp. 341–352.
  • Zhang, W., White, J. C., Abraham, A. M. and Mi, C. C. (2015a). Loosely Coupled Transformer Structure and Interoperability Study for EV Wireless Charging Systems. IEEE Transactions on Power Electronics, 30, pp. 6356–6367.
  • Zhang, W., Wong, S.-C., Tse, C. K. and Chen, Q. (2014a). Analysis and Comparison of Secondary Series and Parallel-Compensated Inductive Power Transfer Systems Operating for Optimal Efficiency and Load-Independent Voltage-Transfer Ratio. IEEE Transactions on Power Electronics, 29, pp. 2979–2990.
  • Zhang, Y., Lu, T., Zhao, Z., Chen, K., He, F. and Yuan, L. (2015b). Wireless Power Transfer to Multiple Loads Over Various Distances Using Relay Resonators. IEEE Microwave and Wireless Components Letters, 25, pp. 337–339.
  • Zhang, Y., Zhao, Z. and Lu, T. (2015c). Quantitative Analysis of System Efficiency and Output Power of Four-Coil Resonant Wireless Power Transfer. IEEE Journal of Emerging and Selected Topics in Power Electronics, 3, pp. 184–190.
  • Zhang, Z. and Chau, K. T. (2015). Homogeneous Wireless Power Transfer for Move-and-Charge. Overview of Wireless Power Transfer Technologies for Electric Vehicle Battery Charging. IEEE Transaction on Power Electronics, 30, pp. 6213–6220.
  • Zhang, Z., Chau, K. T., Liu, C., Qiu, C. and Lin, F. (2014b). An Efficient Wireless Power Transfer System with Security Considerations for Electric Vehicle Applications. Journal of Applied Physics, 115, p. 17A328.
  • Zhang, Z., Chau, K. T., Qiu, C. and Liu, C. (2015d). Energy Encryption for Wireless Power Transfer. IEEE Transactions on Power Electronics, 30, pp. 5237–5246.
  • Zhang, Z., Pang, H., Georgiadis, A. and Cecati, C. (2019). Wireless Power Transfer—An Overview. IEEE Transactions on Industrial Electronics, 66, pp. 1044–1058.
  • Zhong, W. and Hui, S. Y. R. (2015). Maximum Energy Efficiency Tracking for Wireless Power Transfer Systems. IEEE Transactions on Power Electronics, 30, pp. 4025–4034.
  • Zhong, W. and Hui, S. Y. R. (2018). Maximum Energy Efficiency Operation of Series-Series Resonant Wireless Power Transfer Systems Using On-Off Keying Modulation. IEEE Transactions on Power Electronics, 33, pp. 3595–3603.
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