TitlePerformance analysis of the sensorless adaptive sliding-mode neuro-fuzzy control of the induction motor drive with MRAS-type speed estimator
Journal titleBulletin of the Polish Academy of Sciences: Technical Sciences
NumerNo 1 March
Divisions of PASNauki Techniczne
PublisherPolish Academy of Sciences
IdentifierISSN 0239-7528, eISSN 2300-1917
ReferencesVas P. (1998), Sensorless Vector and Direct Torque Control. ; Kazmierkowski M. (2002), Control in Power Electronics - Selected Problems. ; Finch J. (2008), Controlled AC electrical drives, IEEE Trans. Industrial Electronics, 55, 2, 481, doi.org/10.1109/TIE.2007.911209 ; Lin F. (1998), Comparison of sliding-mode and fuzzy neural network control for motor-toggle servo-mechanism, IEEE Trans. Mechatronics, 3, 4, 302, doi.org/10.1109/3516.736164 ; Lin F. (2001), Self-constructing fuzzy neural network speed controller for permanent-magnet synchronous motor drive, IEEE Trans. on Fuzzy Systems, 9, 5, 751, doi.org/10.1109/91.963761 ; Orlowska-Kowalska T. (2006), Adaptive neuro-fuzzy control of the sensorless induction motor drive system, null, 1, 1836. ; Orlowska-Kowalska T. (2007), Control of the drive system with stiff and elastic couplings using adaptive neuro-fuzzy approach, IEEE Trans. Ind. Electronics, 54, 1, 228, doi.org/10.1109/TIE.2006.888787 ; Orlowska-Kowalska T. (2008), Damping of torsional vibrations in two-mass system using adaptive sliding neuro-fuzzy approach, IEEE Trans. Industrial Informatics, 4, 1, 47, doi.org/10.1109/TII.2008.916054 ; Orlowska-Kowalska T. (2003), Sensorless Induction Motor Drives. ; Holtz J. (2006), Sensorless control of induction machines - with or without signal injection?, IEEE Trans. Ind. Electronics, 53, 1, 7, doi.org/10.1109/TIE.2005.862324 ; Tamai S. (1987), Speed sensorless vector control of im with model reference adaptive system, IEEE Industry Appl. Society 27th Annual Meeting IAS'1987, 1, 189. ; Schauder S. (1992), Adaptive speed identification for vector control of induction motors without rotational transducers, IEEE Trans. Industry Applications, 28, 5, 1054, doi.org/10.1109/28.158829 ; Rashed M. (2004), A stable back-EMF MRAS-based sensorless low-speed induction motor drive insensitive to stator resistance variation, IEEE Proc. - Electric Power Applications, 151, 6, 685, doi.org/10.1049/ip-epa:20040609 ; Morawiec M. (2010), Voltage multiscalar control of induction machine supplied by current source converter, IEEE Int. Symposium on Industrial Electronics (ISIE), 1. ; Kubota H. (1993), DSP-based speed adaptive flux observer of induction motor, IEEE Trans. Industry Applications, 29, 2, 344, doi.org/10.1109/28.216542 ; Orlowska-Kowalska T. (2001), Dynamical performances of sensorless induction motor drive with different flux and speed observers, null, 1. ; Orlowska-Kowalska T. (2006), Dynamical properties of induction motor drive with novel MRAS estimator, Electrical Review, 82, 11, 35. ; Kubota H. (2002), Stator resistance estimation for sensorless induction motor drives under regenerating condition, null, 1, 426. ; Saejia M. (2006), Averaging analysis approach for stability analysis of speed-sensorless induction motor drives with stator resistance estimation, IEEE Trans. Industrial Electronics, 53, 1, 163. ; Orlowska-Kowalska T. (2010), Stator current-based mras estimator for a wide range speed-sensorless induction motor drive, IEEE Trans. Industrial Electronics, 57, 4, 1296, doi.org/10.1109/TIE.2009.2031134 ; Yager R. (1994), Essentials of Fuzzy Modeling and Control. ; Bogosyan S. (2007), Braided extended kalman filters for sensorless estimation in induction motors at high-low/zero speed, IET Proc. - Control Theory and Applications, 1, 4, 987, doi.org/10.1049/iet-cta:20060329 ; Żabiński T. (2010), Tuning P-PI and PI-PI controllers for electrical servos, Bull Pol Ac.: Tech, 58, 1, 51.