Fuzzy Logic Speed Controller for Direct Vector Control of Induction Motor
This paper presents a new method for the
implementation of a direct rotor flux control (DRFOC) of induction
motor (IM) drives. It is based on the rotor flux components
regulation. The d and q axis rotor flux components feed proportional
integral (PI) controllers. The outputs of which are the target stator
voltages (vdsref and vqsref). While, the synchronous speed is depicted at
the output of rotor speed controller. In order to accomplish variable
speed operation, conventional PI like controller is commonly used.
These controllers provide limited good performances over a wide
range of operations even under ideal field oriented conditions. An
alternate approach is to use the so called fuzzy logic controller. The
overall investigated system is implemented using dSpace system
based on digital signal processor (DSP). Simulation and experimental
results have been presented for a one kw IM drives to confirm the
validity of the proposed algorithms.
[1] A. Rubaai, M. J. Castro Sitiriche and A. R. Ofoli, "DSP based laboratory
implementation of hybrid fuzzy PID controller using genetic
optimization for high performance motor drives", IEEE Trans. On
Industry. Applications, vol. 44, pp. 1977-1986, Nov. /Dec. 2008.
[2] L. Sbita., Contribution in digital control of systems: Application to
digital control of sensorless induction motor drive, dissertation of HDR.
National Engineering School of Sfax, Tunisia, Mar. 2008, p. 153.
[3] M. Ben Hamed, "Contribution ├á la commande numérique et synthèse
muli algorithmique d-observation de flux et de la vitesse d-un actionneur
├á induction". PhD. Dissertation, Electrical Dep., Université of Gabes
Tunisia, Mar. 2009.
[4] X. Dong and al., "Fuzzy-logic-based V/f control of an induction motor
for a DC grid power-leveling system using flywheel energy storage
equipment", IEEE Trans. on Industry. Electronics, vol. 56, pp. 3161-
3168, Aug. 2009.
[5] F. Blaschke, "The principle of field orientation applied to the transvector
closed loop control system for rotating field machines", Siemens Rev.,
vol. 34, pp. 217-220, May. 1972.
[6] N. Slvatore and al., "Optimization of delayed state kalman filter based
algorithm via differential evolution for sensorless control of induction
motors", IEEE Trans. On Industry. Electronics, vol. 57, pp. 385-394,
Jan. 2010.
[7] S. M. Gadoue, D. Giaouris and J. W.Finch., "MRAS sensorless vector
control of an induction motor using new sliding-mode and fuzzy-logic
adaptation", IEEE Trans. on Enery Conversion, vol. 99, pp. 1-9, Dec.
2009.
[8] H. K. Khalil, E.G. Strangas, S. Jurkovic., "Speed observer and reduced
nonlinear model for sensorless control of induction motors", IEEE
Trans. On Control. System Technology, vol. 17, pp. 327-339, Mar.
2009.
[9] M. Missiala and al., "Fuzzy self-tuning speed control of an indirect
field-oriented control induction motor drive", IEEE Trans. On Industry
Applications, vol. 44, pp. 1732-1740, Nov. /Dec. 2008.
[10] A. Boglietti, A. Cavagnino and D. Staton., "Determination of critical
parameters in electrical machine thermal models", IEEE Trans. On
Industry Applications, vol. 44, pp. 1150-1159, Jul. /Aug. 2008.
[11] K. Rae and J. Kiseok, "Induction motor rotor temperature estimation
based on a high-frequency model of a rotor bar", IEEE Trans. On
Industry Applications, vol. 45, no. 4, pp. 1267-1275, Jul. 2009.
[12] Z. Gao and al., "A sensorless adaptive stator winding temperature
estimator for mains fed induction machines with continuous operation
periodic duty cycles", IEEE Trans. On Industry Applications, vol. 44,
pp. 1533-1534, Sept. /Oct. 2008.
[13] C. Lascu,, I. Boldea and F. Blaabjerg., , "Class of speed-sensorless
sliding-mode observers for high-performance induction motor drives",
IEEE Trans. On Industry Electronics, vol. 56, pp. 3394-3403, Sept.
2009.
[14] S. Maiti and al., "Model reference adaptive controller based rotor
resistance and speed estimation techniques for vector induction motor
drive utilizing reactive power", IEEE Trans. on Industry Electronics,
vol. 55, pp. 594-601, Feb. 2008.
[15] M. S. Zaky and al., "Wide-speed-range estimation with online parameter
identification schemes of sensorless induction motor drives", IEEE
Trans. On Industry Electronics, vol. 56, pp. 4035-4042, Oct. 2009.
[16] S. Hasan and I. Husain., "A Luenberger-sliding mode observer for
online parameter estimation and adaptation in high-performance
induction motor drives", IEEE Trans. on Industry Applications, vol. 45,
pp. 772-781, Mar. /Apr. 2009.
[17] K. Szabut, T. Orlowska Kowalska and M. Dybkowski., "Indirect
adaptive control of induction motor drive system with an elastic
coupling", IEEE Trans. on Industry Electronics, vol. 56, pp. 4035-4042,
Oct. 2009.
[18] S. Rao, M. Buss and S. Utkin, "Simultaneous state and parameter
estimation in induction motors using first and second order sliding
modes", IEEE Trans. On Industry Electronics, vol. 57, pp. 3369-3376,
Sept. 2009.
[19] S. M. Gadoue, D. Giouris and J. W. Finch, "Sensorless control of
induction motor drives at very low and zero speeds using neural network
flux observers", IEEE Trans. On Industry Electronics, vol. 56, pp.
3029-3039, Aug. 2009.
[20] A. Ba Razzouk and al.,"Field oriented control of induction motors using
neural networks decouplers", IEEE Trans. On Industry Power
Electronics, vol. 12, pp. 752-763, Jul. 1997.
[21] M. Comanescu., "An Induction-motor speed estimator based on integral
sliding-mode current control", IEEE Trans. On Industry Electronics,
vol. 56, pp. 3414-3423, Sept. 2009.
[22] A. Trentin and al., "Optimized commissioning method for enhanced
vector control of high-power induction motor drives", IEEE Trans. On
Industry Electronics, vol. 56, pp. 1708-1717, Apr. 2009.
[23] B. Verselic and al., "High performance position control of induction
motor using discrete time sliding mode control", IEEE Trans. Ind.
Electron., vol. 55, pp. 3809-3817, Oct. 2008.
[24] E. S. de Santana and al., "A predictive algorithm for controlling speed
and rotor flux of induction motor", IEEE Trans. On Industry
Electronics, vol. 55, pp. 4398-4407, Oct. 2008.
[25] A. Consoli and al., "Flux and voltage calculations of induction motors
supplied by low- and high-frequency currents", IEEE Trans. Ind.
Applicat., vol. 45, no. 2, pp. 737-746, Mar. 2009.
[26] M. Ghanes and Z. Gang, "On sensorless induction motor drive sliding
mode observer and output feedback controller", IEEE Trans. Ind.
Electron., vol. 56, pp. 3404-3413, Sept. 2009.
[27] S. M. A. Cruz. and al., "A New model-based technique for the diagnosis
of rotor faults in RFOC induction motor drives", IEEE Trans. Ind.
Electron., vol. 55, pp. 4218-4228, Dec. 2008.
[28] T. S. Kwon, M. H. Shin and D. S. Hyun., "Adaptive fuzzy control of
nonlinear systems in pure feedback form based on input-to-state
stability", IEEE Trans. Fuzzy Sys., vol. 18, pp. 80 - 93, Feb. 2010.
[1] A. Rubaai, M. J. Castro Sitiriche and A. R. Ofoli, "DSP based laboratory
implementation of hybrid fuzzy PID controller using genetic
optimization for high performance motor drives", IEEE Trans. On
Industry. Applications, vol. 44, pp. 1977-1986, Nov. /Dec. 2008.
[2] L. Sbita., Contribution in digital control of systems: Application to
digital control of sensorless induction motor drive, dissertation of HDR.
National Engineering School of Sfax, Tunisia, Mar. 2008, p. 153.
[3] M. Ben Hamed, "Contribution ├á la commande numérique et synthèse
muli algorithmique d-observation de flux et de la vitesse d-un actionneur
├á induction". PhD. Dissertation, Electrical Dep., Université of Gabes
Tunisia, Mar. 2009.
[4] X. Dong and al., "Fuzzy-logic-based V/f control of an induction motor
for a DC grid power-leveling system using flywheel energy storage
equipment", IEEE Trans. on Industry. Electronics, vol. 56, pp. 3161-
3168, Aug. 2009.
[5] F. Blaschke, "The principle of field orientation applied to the transvector
closed loop control system for rotating field machines", Siemens Rev.,
vol. 34, pp. 217-220, May. 1972.
[6] N. Slvatore and al., "Optimization of delayed state kalman filter based
algorithm via differential evolution for sensorless control of induction
motors", IEEE Trans. On Industry. Electronics, vol. 57, pp. 385-394,
Jan. 2010.
[7] S. M. Gadoue, D. Giaouris and J. W.Finch., "MRAS sensorless vector
control of an induction motor using new sliding-mode and fuzzy-logic
adaptation", IEEE Trans. on Enery Conversion, vol. 99, pp. 1-9, Dec.
2009.
[8] H. K. Khalil, E.G. Strangas, S. Jurkovic., "Speed observer and reduced
nonlinear model for sensorless control of induction motors", IEEE
Trans. On Control. System Technology, vol. 17, pp. 327-339, Mar.
2009.
[9] M. Missiala and al., "Fuzzy self-tuning speed control of an indirect
field-oriented control induction motor drive", IEEE Trans. On Industry
Applications, vol. 44, pp. 1732-1740, Nov. /Dec. 2008.
[10] A. Boglietti, A. Cavagnino and D. Staton., "Determination of critical
parameters in electrical machine thermal models", IEEE Trans. On
Industry Applications, vol. 44, pp. 1150-1159, Jul. /Aug. 2008.
[11] K. Rae and J. Kiseok, "Induction motor rotor temperature estimation
based on a high-frequency model of a rotor bar", IEEE Trans. On
Industry Applications, vol. 45, no. 4, pp. 1267-1275, Jul. 2009.
[12] Z. Gao and al., "A sensorless adaptive stator winding temperature
estimator for mains fed induction machines with continuous operation
periodic duty cycles", IEEE Trans. On Industry Applications, vol. 44,
pp. 1533-1534, Sept. /Oct. 2008.
[13] C. Lascu,, I. Boldea and F. Blaabjerg., , "Class of speed-sensorless
sliding-mode observers for high-performance induction motor drives",
IEEE Trans. On Industry Electronics, vol. 56, pp. 3394-3403, Sept.
2009.
[14] S. Maiti and al., "Model reference adaptive controller based rotor
resistance and speed estimation techniques for vector induction motor
drive utilizing reactive power", IEEE Trans. on Industry Electronics,
vol. 55, pp. 594-601, Feb. 2008.
[15] M. S. Zaky and al., "Wide-speed-range estimation with online parameter
identification schemes of sensorless induction motor drives", IEEE
Trans. On Industry Electronics, vol. 56, pp. 4035-4042, Oct. 2009.
[16] S. Hasan and I. Husain., "A Luenberger-sliding mode observer for
online parameter estimation and adaptation in high-performance
induction motor drives", IEEE Trans. on Industry Applications, vol. 45,
pp. 772-781, Mar. /Apr. 2009.
[17] K. Szabut, T. Orlowska Kowalska and M. Dybkowski., "Indirect
adaptive control of induction motor drive system with an elastic
coupling", IEEE Trans. on Industry Electronics, vol. 56, pp. 4035-4042,
Oct. 2009.
[18] S. Rao, M. Buss and S. Utkin, "Simultaneous state and parameter
estimation in induction motors using first and second order sliding
modes", IEEE Trans. On Industry Electronics, vol. 57, pp. 3369-3376,
Sept. 2009.
[19] S. M. Gadoue, D. Giouris and J. W. Finch, "Sensorless control of
induction motor drives at very low and zero speeds using neural network
flux observers", IEEE Trans. On Industry Electronics, vol. 56, pp.
3029-3039, Aug. 2009.
[20] A. Ba Razzouk and al.,"Field oriented control of induction motors using
neural networks decouplers", IEEE Trans. On Industry Power
Electronics, vol. 12, pp. 752-763, Jul. 1997.
[21] M. Comanescu., "An Induction-motor speed estimator based on integral
sliding-mode current control", IEEE Trans. On Industry Electronics,
vol. 56, pp. 3414-3423, Sept. 2009.
[22] A. Trentin and al., "Optimized commissioning method for enhanced
vector control of high-power induction motor drives", IEEE Trans. On
Industry Electronics, vol. 56, pp. 1708-1717, Apr. 2009.
[23] B. Verselic and al., "High performance position control of induction
motor using discrete time sliding mode control", IEEE Trans. Ind.
Electron., vol. 55, pp. 3809-3817, Oct. 2008.
[24] E. S. de Santana and al., "A predictive algorithm for controlling speed
and rotor flux of induction motor", IEEE Trans. On Industry
Electronics, vol. 55, pp. 4398-4407, Oct. 2008.
[25] A. Consoli and al., "Flux and voltage calculations of induction motors
supplied by low- and high-frequency currents", IEEE Trans. Ind.
Applicat., vol. 45, no. 2, pp. 737-746, Mar. 2009.
[26] M. Ghanes and Z. Gang, "On sensorless induction motor drive sliding
mode observer and output feedback controller", IEEE Trans. Ind.
Electron., vol. 56, pp. 3404-3413, Sept. 2009.
[27] S. M. A. Cruz. and al., "A New model-based technique for the diagnosis
of rotor faults in RFOC induction motor drives", IEEE Trans. Ind.
Electron., vol. 55, pp. 4218-4228, Dec. 2008.
[28] T. S. Kwon, M. H. Shin and D. S. Hyun., "Adaptive fuzzy control of
nonlinear systems in pure feedback form based on input-to-state
stability", IEEE Trans. Fuzzy Sys., vol. 18, pp. 80 - 93, Feb. 2010.
@article{"International Journal of Electrical, Electronic and Communication Sciences:56320", author = "Ben Hamed M. and Sbita L", title = "Fuzzy Logic Speed Controller for Direct Vector Control of Induction Motor", abstract = "This paper presents a new method for the
implementation of a direct rotor flux control (DRFOC) of induction
motor (IM) drives. It is based on the rotor flux components
regulation. The d and q axis rotor flux components feed proportional
integral (PI) controllers. The outputs of which are the target stator
voltages (vdsref and vqsref). While, the synchronous speed is depicted at
the output of rotor speed controller. In order to accomplish variable
speed operation, conventional PI like controller is commonly used.
These controllers provide limited good performances over a wide
range of operations even under ideal field oriented conditions. An
alternate approach is to use the so called fuzzy logic controller. The
overall investigated system is implemented using dSpace system
based on digital signal processor (DSP). Simulation and experimental
results have been presented for a one kw IM drives to confirm the
validity of the proposed algorithms.", keywords = "DRFOC, fuzzy logic, variable speed drives, control,IM and real time.", volume = "3", number = "4", pages = "740-7", }
