Partha Sarathi Subudhi, Krithiga Subramanian, and Binu Ben Jose Dharmaian Retnam
[1] K. Kasturi, C.K. Nayak, and M.R. Nayak, Electric vehicles management enabling G2V and V2G in smart distribution system for maximizing profits using MOMVO, Int. Trans. Electr. Energy Syst., 2019, 1–17. [2] J. Moon, H. Hwang, B. Jo, H.-A. Shin, and S.-W. Kim, Design of a 5-W power receiver for 6.78 MHz resonant wireless power transfer system with power supply switching circuit, IEEE Transactions on Consumer Electronics, 62(4), 2016, 349–354. [3] M. Yilmaz and P.T. Krein, Review of battery charger topologies, charging power levels, and infrastructure for plug-in electric and hybrid vehicles, IEEE Transactions on Power Electronics, 28(5), 2013, 2151–2169. [4] Z. Li, C. Zhu, J. Jiang, K. Song, and G. Wei, A 3-kW wireless power transfer system for sightseeing car super capacitor charge, IEEE Transactions on Power Electronics, 32(5), 2017, 3301–3316. [5] C. Panchal, S. Stegen, and J. Lu, Review of static and dynamic wireless electric vehicle charging system, Engineering Science and Technology, An International Journal, 21(5), 2018, 922–937. [6] C. Xia, W. Wang, Y. Liu, K. Lin, Y. Wang, and X. Wu, A bidirectional wireless power transfer system for an electric vehicle with a relay circuit, Turkish Journal of Electrical Engineering & Computer Sciences, 25, 2017, 3037–3051. [7] S.B. Lee, S. Ahn, and I.G. Jang, Simulation-based feasibility study on the wireless charging railway system with a ferrite less primary module, IEEE Transactions on Vehicular Technology, 66(2), 2017, 1004–1010. [8] S.Y. Choi, B.W. Gu, S.Y. Jeong, and C.T. Rim, Advances in wireless power transfer systems for roadway-powered electric vehicles, IEEE Journal of Emerging and Selected Topics in Power Electronics, 3(1), 2015, 18–36. [9] Z. Pantic, S. Bai, and S. Lukic, Inductively coupled power transfer for continuously powered electric vehicles, 2009 IEEE Vehicle Power and Propulsion Conference, IEEE, 2009, 1271–1278. [10] C.-S. Wang, O. Stielau, and G. Covic, Design considerations for a contactless electric vehicle battery charger, IEEE Transactions on Industrial Electronics, 52(5), 2005, 1308–1314. [11] Y.-M. Wi, J.-U. Lee, and S.-K. Joo, Electric vehicle charging method for smart homes/buildings with a photovoltaic system, IEEE Transactions on Consumer Electronics, 59(2), 2013, 323–328. [12] G. Buja, M. Bertoluzzo, and K.N. Mude, Design and experimentation of WPT charger for electric city car, IEEE Transactions on Industrial Electronics, 62(12), 2015, 7436–7447. 139 [13] W. Eberle and F. Musavi, Overview of wireless power transfer technologies for electric vehicle battery charging, IET Power Electronics, 7(1), 2014, 60–66. [14] A.A.S. Mohamed, A. Berzoy, F.G.N. de Almeida, and O. Mohammed, Modeling and assessment analysis of various compensation topologies in bidirectional IWPT system for EV applications, IEEE Transactions on Industry Applications, 53(5), 2017, 4973–4984. [15] A.J. Moradewicz and M.P. Kazmierkowski, Contactless energy transfer system with FPGA-controlled resonant converter, IEEE Transactions on Industrial Electronics, 57(9), 2010, 3181–3190. [16] T. Imura, T. Yasuda, K. Oshima, T. Nayuki, M. Sato, and A. Oshima, Wireless power transfer for electric vehicle at the kilohertz band, IEEJ Transactions on Electrical and Electronic Engineering, 11, 2016, 91–99. [17] J. Sallan, J. Villa, A. Llombart, and J. Sanz, Optimal design of ICPT systems applied to electric vehicle battery charge, IEEE Transactions on Industrial Electronics, 56(6), 2009, 2140–2149. [18] W. Zhang and C.C. Mi, Compensation topologies of high-power wireless power transfer systems, IEEE Transactions on Vehicular Technology, 65(6), 2016, 4768–4778. [19] S. Samanta, A.K. Rathore, and D.J. Thrimawithana, Bidirectional current-fed half-bridge (C) (LC)–(LC) configuration for inductive wireless power transfer system, IEEE Transactions on Industry Applications, 53(4), 2017, 4053–4062. [20] S.-Y. Cho, I.-O. Lee, S.C. Moon, G.-W. Moon, B.-C. Kim, and K.Y. Kim, Constant current charging in series-series compensated non-radiative wireless power link, 2013 IEEE International Symposium on Circuits and Systems (ISCAS2013), Vol. 3, 2013, 2792–2795. [21] S. Moon, B.-c. Kim, S.-y. Cho, C.-h. Ahn, and G.-w. Moon, Analysis and design of a wireless power transfer system with an intermediate coil for high efficiency, IEEE Transactions on Industrial Electronics, 61(11), 2014, 5861–5870. [22] H. Hwang, J. Moon, B. Lee, C.-h. Jeong, and S.-w. Kim, An analysis of magnetic resonance coupling effects on wireless power transfer by coil inductance and placement, IEEE Transactions on Consumer Electronics, 60(2), 2014, 203–209. [23] S.-Y. Cho, I.-O. Lee, S. Moon, G.-W. Moon, B.-C. Kim, and K. Y. Kim, Series–series compensated wireless power transfer at two different resonant frequencies, 2013 IEEE ECCE Asia Down under, Vol. 2, 2013, 1052–1058. [24] J.L. Villa, J. Sallan, J.F. Sanz Osorio, and A. Llombart, High-misalignment tolerant compensation topology for ICPT systems, IEEE Transactions on Industrial Electronics, 59(2), 2012, 945–951. [25] K. Song, Z. Li, J. Jiang, and C. Zhu, Constant current/voltage charging operation for series–series and series–parallel compensated wireless power transfer systems employing primary-side controller, IEEE Transactions on Power Electronics, 8993(3), 2017, 1–8. [26] A. Swain, D. Almakhles, Y. Hou, N. Patel, and U. Madawala, A sigma-delta modulator based PI controller for bidirectional inductive power transfer systems, IEEE 2nd Annual Southern Power Electronics Conf. (SPEC), 2016, 1–6.
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