Abstract
High-speed machines have been widely employed in applications like smaller size of spindle motors, large chiller motors, micro-turbine generators, aircraft generators, compressors, and gas-turbines owing to their high power density and high efficiency.
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References
D. Gerada, A. Mebarki, N. L. Brown, C. Gerada, A. Cavagnino, A. Boglietti, High-speed electrical machines: technologies trends and developments. IEEE Trans. Ind. Electron. 61(6), 2946–2959 (June 2014)
J.-S. Yim, S.-K. Sul, B.-H. Bae, N. R. Patel, and S. Hiti, Modified current control schemes for high-performance permanent-magnet AC drives with low sampling to operating frequency ratio. IEEE Trans. Ind. Appl. 45(2), 763–771 (March/April 2009)
M. Abrate, G. Griva, F. Profumo, A. Tenconi, High speed sensorless fuzzy-like Luenberger observer. Proc. IEEE PESC. 1, 477–481 (September 1999)
G. Griva, F. Profumo, L. Rosell, R. Bojoi, Optimization of fuzzy-like Luenberger observer for high speed sensorless induction motor drives using genetic algorithms. Proc. IAS. 2, 1268–1274 (October 2000)
Y. Zhao, W. Qiao, L. Wu, Improved rotor position and speed estimators for sensorless control of interior permanent-magnet synchronous machines. IEEE J. Emerg. Sel. Topics Power Electron. 2(3), 627–639 (September 2014)
B.-H. Bae, S.-K. Sul, A compensation method for time delay of full-digital synchronous frame current regulator of PWM AC drives. IEEE Trans. Ind. Appl. 39(3), 802–810 (May 2003)
J. Shen, S. Schröder, H. Stagge, R. W. De Doncker, Precise modeling and analysis of DQ-frame current controller for high power converters with low pulse ratio. Proc. IEEE Energy Convers. Congr. Expo., 61–68 (September 2012)
J. Holtz, J. Quan, J. Pontt, J. Rodriguez, P. Newman, H. Miranda, Design of fast and robust current regulators for high-power drives based on complex state variables. IEEE Trans. Ind. Appl. 40(5), 1388–1397 (September 2004)
W. Xu, R. D. Lorenz, Low-sampling-frequency stator flux linkage observer for interior permanent-magnet synchronous machines. IEEE Trans. Ind. Appl. 51(5), 3932–3942 (September/October 2015)
Y. Wang, S. Tobayashi, R. D. Lorenz, A low-switching-frequency flux observer and torque model of deadbeat–direct torque and flux control on induction machine drives. IEEE Trans. Ind. Appl. 51(3), 2255–2267 (May/June 2015)
Y. Zhao, W. Qiao, L. Wu, Sensorless control for IPMSMs based on a multilayer discrete-time sliding-mode observer. Proc. IEEE Energy Convers. Congr. Expo, 1788–1795 (September 2012)
M. Hinkkanen, H. A. A. Awan, Z. Qu, T. Tuovinen, F. Briz, Current control for synchronous motor drives: direct discrete-time pole-placement design. IEEE Trans. Ind. Appl. 52(2), 1530–1541 (March/April 2016)
G. Zhang, G. Wang, D. Xu, Y. Yu, Discrete-time low-frequency-ratio synchronous-frame full-order observer for position sensorless IPMSM drives. IEEE J. Emerging Select. Topics Power Electron. 5(2), 870–879 (June 2017)
H. A. A. Awan, T. Tuovinen, S. E. Saarakkala, M. Hinkkanen, Discrete-time observer design for sensorless synchronous motor drives. IEEE Trans. Ind. Appl. 52(5), 3968–3979 (September/October 2016)
K. Hongrae, M. W. Degner, J. M. Guerrero, F. Briz, R. D. Lorenz, Discrete-time current regulator design for AC machine drives. IEEE Trans. Ind. Appl. 46(4), 1425–1435 (July/August 2010)
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Wang, G., Zhang, G., Xu, D. (2020). Low-Frequency Ratio Sensorless Control for High-Speed PMSM Drives. In: Position Sensorless Control Techniques for Permanent Magnet Synchronous Machine Drives. Springer, Singapore. https://doi.org/10.1007/978-981-15-0050-3_7
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DOI: https://doi.org/10.1007/978-981-15-0050-3_7
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