Chukwuemeka C. Awah, Ogbonnaya I. Okoro, Udochukwu B. Akuru, and Stephen E. Oti


  1. [1] S. Chaithongsuk, B.N. Mobarakeh, N. Takorabet, J.P. Caron, and F.M. Tabar, Optimal design of PM motors to achieve efficient flux weakening strategy in variable speed control applications, Proc. IEEE Int. Conf. on Electrical Machines, Rome, Italy, 2010, 1–6.
  2. [2] A. Pouramin and S.M. Madani, New interior PM rotor design with high flux-weakening capability, Proc. IEEE Int. Conf. on Electrical Machines and Drives, Miami, USA, 2009, 958–963.
  3. [3] F. Alessandro, L. Alberti, and N. Bianchi, Performance comparison between switching-flux and IPM machines with rare-earth and ferrite PMs, IEEE Transactions on Industry Applications, 50(6), 2014, 3708–3716.
  4. [4] X. Zhu, J. Huang, L. Quan, Z. Xiang, and B. Shi, Comprehensive sensitivity analysis and multiobjective optimization research of permanent magnet flux-intensifying motors, IEEE Transactions on Industrial Electronics, 66(4), 2019, 2613–2627.
  5. [5] J. Pang, W. Liu, N. Jiao, J. Wang, and P. Ma, Calculation of cross-coupling inductance and electromagnetic torque in wound-rotor synchronous starter/generator, IEEE Transactions on Industrial Electronics, 66(7), 2019, 5115–5123.
  6. [6] S.E. Rauch and L.J. Johnson, Design principles of the flux-switch alternators, AIEE Transactions, 74(3), 1955, 1261–1268.
  7. [7] E. Hoang, A.H. Ben Ahmed, and J. Lucidarme, Switching flux permanent magnet polyphased synchronous machines, Proc. European Power Electronics (EPE) Conference, Trondheim, Norway, 1997, 903–908.
  8. [8] Z.Q. Zhu, Switched flux permanent magnet machines – innovation continues, Proc. of Int. Conf. on Electrical Machines and Systems (ICEMS), Beijing, China, 2011, 1–10.
  9. [9] G. Zhang, W. Hua, and P. Han, Quantitative evaluation of the topologies and electromagnetic performances of dual-three-phase flux-switching machines, IEEE Transactions on Industrial Electronics, 65 (11), 2018, 9157–9167.
  10. [10] D. Kim, H. Hwang, S. Bae and C. Lee, Analysis and design of double-stator flux-switching permanent magnet machine using ferrite magnet in hybrid electric vehicles, IEEE Transactions on Magnetics, 52(7), 2016, 8106604.
  11. [11] P. Taras, G.J. Li, Z.Q. Zhu, M.P. Foster, and D.A. Stone, Combined multiphysics model of switched flux PM machines under fault operations, Transactions on Industrial Electronics, 66 (9), 2019, 6737–6745.
  12. [12] Z.Z. Wu and Z.Q. Zhu, Analysis of magnetic gearing effect in partitioned stator switched flux PM machines, IEEE Transactions on Energy Conversion, 31 (4), 2016, 1239–1249.
  13. [13] C.C. Awah, O.I. Okoro, and E. Chikuni, The impact of design parameters on the average torque of double-stator switched flux PM machines, Proc. EAI Int. Conf. on Research, Innovation and Development (ACRID), Victoria Falls, Zimbabwe, 2017, 120–129.
  14. [14] G. Qi, J.T. Chen, Z.Q. Zhu, D. Howe, L.B. Zhou and C.L. Gu, Influence of skew and cross-coupling on dand q-axis inductances and flux-weakening performance of PM brushless AC machines, IEEE Transactions on Magnetics, 45(5), 2009, 2110–2117.
  15. [15] L. Sun, Z. Zhang, L. Yu, and X. Gu, Development and analysis of a new hybrid excitation brushless DC generator with flux modulation effect, IEEE Transactions on Industrial Electronics, 66(6), 2019, 4189–4198.
  16. [16] Y. Sui, Z. Yin, M. Wang, B. Yu, and P. Zheng, A tubular staggered-teeth transverse-flux PMLM with circumferentially distributed three-phase windings, IEEE Transactions on Industrial Electronics, 66(6), 2019, 4837–4848.
  17. [17] S.W. Christian, H. Polinder, and J.A. Ferreira, High-torque-density high-efficiency flux-switching PM machine for aerospace applications, IEEE Journal of Emerging and Selected Topics in Power Electronics, 1(4), 2013, 327–336.
  18. [18] H. Wei, H. Zhang, M. Cheng, J. Meng, and C. Hou, An outer-rotor flux-switching permanent magnet machine with wedge-shaped magnets for in-wheel light traction, IEEE Transactions on Industrial Electronics, 64(1), 2017, 69–80.
  19. [19] F. Papini and M. Osama, Electromagnetic design of an interior permanent magnet motor for vehicle traction, Proc. Int. Conf. Electrical Machines (ICEM), Alexandroupoli, Greece, 2018, 205–211.

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