Details

Title

Dynamic variables limitation for backstepping control of induction machine and voltage source converter

Journal title

Archives of Electrical Engineering

Yearbook

2012

Volume

vol. 61

Numer

No 3 September

Authors

Keywords

power electronics converters ; backstepping control ; dynamic variables limitation

Divisions of PAS

Nauki Techniczne

Coverage

389-410

Publisher

Polish Academy of Sciences

Date

2012

Type

Artykuły / Articles

Identifier

eISSN: 2300-2506 ; ISSN: 1427-4221

References

Young Hwang (2008), Robust adaptive backstepping control for efficiency optimization of induction motors with uncertainties. ; Lie Xu (2007), Direct Power Control of Grid Connected Voltage Source Converters, null. ; Ramos C. (2009), A new approach to design high performance current controllers for grid connected voltage source converters. ; Antoniewicz P. (2008), Virtual-Flux-Based Predictive Direct Power Control of AC/DC Converters with Online Inductance Estimation, IEEE Trans. on Industrial Electr, 55, 12. ; Zanchetta P. (2008), Predictive current control for multilevel active rectifiers with reduced Switching frequency, IEEE Trans. on Industrial Electr, 55, 1. ; Borisov K. (2009), Multifunctional VSC Based on a Novel Fortescue Reference Signal Generator, IEEE Trans. on Industrial Electr, 57. ; Malinowski M. (2001), Virtual-flux-based direct power control of three-phase PWM rectifiers, Trans. on Industrial Electr, 37, 4. ; Aurtenechea S. (2007), Predictive control strategy for DC/AC converters based on direct power control, IEEE Trans. on Industrial Electr, 54, 3. ; Krzeminski Z. (1987), Nonlinear control of induction motor, null. ; Payam A. (2006), Nonlinear sliding-mode controller for sensorless speed control of DC servo motor using adaptive backstepping observer, null. ; Krstic M. (1995), Nonlinear and Adaptive Control Design. ; Tan H. (1999), Adaptive Backstepping control of induction motor with uncertainties, null, 1. ; Adamowicz M. (2005), Minimum-time minimum-loss speed sensorless control of induction motors under nonlinear control, Compatibility in Power Electronics. ; Elmaguiri O. (2007), Digital backstepping control of induction motors, IEEE International Symposium on Industrial Electronics, 221, doi.org/10.1109/ISIE.2007.4374602 ; Nemmour A. (2009), Nonlinear control of induction motor based on the combined multi-scalar machine model and backstepping approach, null. ; Robertsson A. (1998), Observer Backstepping and Control Design of Linear Systems, null. ; Drid S. (2007), Robust backstepping vector control for the doubly fed induction motor, IET Control Theory Appl, 1, 4, 861, doi.org/10.1049/iet-cta:20060053 ; Hsin-Jang S. (1999), Nonlinear Sliding-Mode Torque Control with Adaptive Backstepping Approach, IEEE Trans. on Indust. Electronics, 46, 2. ; Hajian M. (2010), Adaptive Nonlinear Direct Torque Control of Sensorless IM Drives With Efficiency Optimization, IEEE Trans. on Indust. Electronics, 57, 3, doi.org/10.1109/TIE.2009.2029592 ; Uddin M. (2009), Development and Implementation of a Nonlinear-Controller-Based IM Drive Incorporating Iron Loss With Parameter Uncertainties, IEEE Trans. on Indust. Electronics, 56, 4, doi.org/10.1109/TIE.2008.2007551 ; Lin Chih-Min (2005), Recurrent-Neural-Network-Based Adaptive-Backstepping Control for Induction Servo motors, IEEE Trans. on Indust. Electronics, 52, 6. ; Tan Y. (2003), Adaptive Backstepping Control and Friction Compensation for AC Servo With Inertia and Load Uncertainties, IEEE Trans. on Indust. Electronics, 50, 5. ; Lin Faa-Jeng (2007), FPGA-Based Adaptive Backstepping Sliding-Mode Control for Linear Induction Motor Drive, IEEE Trans. on Power Electr, 22, 4. ; Carroll J. (1995), Integrator backstepping techniques for the tracking control of permanent magnet brush DC motors, IEEE Trans. On Indust. Appl, 31, 2, doi.org/10.1109/28.370270 ; Trabelsi R. (2010), Backstepping control for an induction motor with an adaptive Backstepping rotor flux observer, null. ; Uddin M. (2009), Development and Implementation of a Nonlinear-Controller-Based IM Drive Incorporating Iron Loss With Parameter Uncertainties, IEEE Trans. on Indust. Electronics, 56, 4. ; Krzeminski Z. (1999), A new speed observer for control system of induction motor, null. ; Morawiec M. (2011), Application of the state observer to identify squire-cage induction machine, Przegląd Elektrotechniczny (Electrical Review) ISSN 0033-2097, 87, 3.

DOI

10.2478/v10171-012-0031-1

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