Design of Power System Stabilizer Based on Sliding Mode Control Theory for Multi- Machine Power System
This paper present a new method for design of power
system stabilizer (PSS) based on sliding mode control (SMC)
technique. The control objective is to enhance stability and improve
the dynamic response of the multi-machine power system. In order to
test effectiveness of the proposed scheme, simulation will be carried
out to analyze the small signal stability characteristics of the system
about the steady state operating condition following the change in
reference mechanical torque and also parameters uncertainties. For
comparison, simulation of a conventional control PSS (lead-lag
compensation type) will be carried out. The main approach is
focusing on the control performance which later proven to have the
degree of shorter reaching time and lower spike.
[1] M.Bouhamida, M.A.Denai, "Robust stabilizer of electric power generator
using H¥ with placement constraints", Jou. of Elec. Eng., Vol. 56,
No.7-8, pp.176-182, 2005.
[2] P.Kundur, "Power system stability and control", McGraw-Hill, 1994.
[3] G.Shahgholian, M.Arezoomand, H.Mahmoodian, "Analysis and simulation
of the single machine infinite bus power system stabilizer and parameters
variation effects", IEEE/ICIAS, pp.167-171, Nov. 2007.
[4] Y.J.Lin, "Systematic approach for the design of a fuzzy power system
stabilizer", IEEE/POWERCON, pp.747-752, Nov. 2004.
[5] V. Bandal, B. Bandyopadhyay, "Robust decentralised output feedback
sliding mode control technique-based power system stabiliser (PSS) for
multimachine power system", IET Con. The. and App., Vol.1, No.5,
pp.1512-1522, Sep. 2007.
[6] A.G.E. Abera, B. Bandyopadhyay, "Digital redesign of sliding mode
control with application to power system stabilizer", IEEE/IECON,
pp.164-169, Orlando, Nov. 2008.
[7] V. Bandal, B. Bandyopadhyay, A.M. Kulkarni, "Decentralized sliding
mode control technique based power system stabilizer for multimachine
power system", IEEE/CCA, pp.55-60, Toronto Canada, Aug. 2005.
[8] S.I. Safie, M. MdShah, A.R. Hasimah, A. Wahab, H.M. Yusri, "Sliding
mode control power system stabilizer for single machine connected to
infinite bus", IEEE/PECON, pp.122-126, Dec. 2008.
[9] J. Faiz, G. Shahgholian, M.Arezoomand, "Analysis and simulation of
the AVR system and parameters variation effects", IEEE/POWRENG,
450-453, April 2007.
[10] G. Cheng, L.Q. Zhan, "Simultaneous coordinated tuning of PSS and
FACTS damping controllers using improved particle swarm
optimization", IEEE/APPEEC, pp.1-4, March 2009.
[11] R. Tiako, K.A. Folly, "Impact of weighting coefficients on the
convergence rate of the steepest descent algorithm used for the design of
an optimal power system stabilizer (OPSS) ", IEEE/AUPEC, pp.1-6,
Sydney, NSW, Dec. 2008.
[12] S. Zhang, F.L. Luo, "An improved simple adaptive control applied to
power system stabilizer", IEEE Tran. on Pow. Elec., Vol.20, No.2,
pp.369-375, Feb. 2009.
[13] C.J. Chen, T.C. Chen, H.J. Ho, C.C. Ou, "PSS design using adaptive
recurrent neural network controller", IEEE/ICNC, Vol.2, pp.277-281,
Tianjin, Dec. 2009.
[14] S. Panda, N.P. Padhy, "Application of genetic algorithm for PSS and
FACTS based controller design", Inte. Jou. of Com. Met., Vol.5, No.4,
pp.607-620, 2008.
[15] R. Pradhan, S. Panda, "Application of Genetic Algorithm based PSS for
two-area AGC system in deregulated scenario", IEEE/NABIC, pp.1207-
1212, Coimbatore, Dec. 2009.
[16] S.S. Lee, S.Y. Li, J.K. Park, "Nonlinear adaptive back-stepping
controller design for power system stabilizer in multi-machine power
systems", IEEE/AACC, pp.2504-2509, Washington USA, June 2008.
[17] Z. Jiang, "Design of a nonlinear power system stabilizer using
synergetic control theory", Elec. Pow. Sys. Res., Vol.79, No.6, pp/855-
862, June 2009.
[18] K.D. Young, V.I. Utkin, U. Ozguner, "A control engineer's guide to
sliding mode control", IEEE Trans. on Con. Sys. Tec., Vol.7, No.3,
pp.328-342, Aug. 2002.
[19] Y. Lee, Y.B. Shtessel, "Comparison of a feedback linearization controller
and sliding mode controllers for a permanent magnet stepper motor",
IEEE/SSST, pp.258-262, Baton Rouge, Mar./April 1996.
[1] M.Bouhamida, M.A.Denai, "Robust stabilizer of electric power generator
using H¥ with placement constraints", Jou. of Elec. Eng., Vol. 56,
No.7-8, pp.176-182, 2005.
[2] P.Kundur, "Power system stability and control", McGraw-Hill, 1994.
[3] G.Shahgholian, M.Arezoomand, H.Mahmoodian, "Analysis and simulation
of the single machine infinite bus power system stabilizer and parameters
variation effects", IEEE/ICIAS, pp.167-171, Nov. 2007.
[4] Y.J.Lin, "Systematic approach for the design of a fuzzy power system
stabilizer", IEEE/POWERCON, pp.747-752, Nov. 2004.
[5] V. Bandal, B. Bandyopadhyay, "Robust decentralised output feedback
sliding mode control technique-based power system stabiliser (PSS) for
multimachine power system", IET Con. The. and App., Vol.1, No.5,
pp.1512-1522, Sep. 2007.
[6] A.G.E. Abera, B. Bandyopadhyay, "Digital redesign of sliding mode
control with application to power system stabilizer", IEEE/IECON,
pp.164-169, Orlando, Nov. 2008.
[7] V. Bandal, B. Bandyopadhyay, A.M. Kulkarni, "Decentralized sliding
mode control technique based power system stabilizer for multimachine
power system", IEEE/CCA, pp.55-60, Toronto Canada, Aug. 2005.
[8] S.I. Safie, M. MdShah, A.R. Hasimah, A. Wahab, H.M. Yusri, "Sliding
mode control power system stabilizer for single machine connected to
infinite bus", IEEE/PECON, pp.122-126, Dec. 2008.
[9] J. Faiz, G. Shahgholian, M.Arezoomand, "Analysis and simulation of
the AVR system and parameters variation effects", IEEE/POWRENG,
450-453, April 2007.
[10] G. Cheng, L.Q. Zhan, "Simultaneous coordinated tuning of PSS and
FACTS damping controllers using improved particle swarm
optimization", IEEE/APPEEC, pp.1-4, March 2009.
[11] R. Tiako, K.A. Folly, "Impact of weighting coefficients on the
convergence rate of the steepest descent algorithm used for the design of
an optimal power system stabilizer (OPSS) ", IEEE/AUPEC, pp.1-6,
Sydney, NSW, Dec. 2008.
[12] S. Zhang, F.L. Luo, "An improved simple adaptive control applied to
power system stabilizer", IEEE Tran. on Pow. Elec., Vol.20, No.2,
pp.369-375, Feb. 2009.
[13] C.J. Chen, T.C. Chen, H.J. Ho, C.C. Ou, "PSS design using adaptive
recurrent neural network controller", IEEE/ICNC, Vol.2, pp.277-281,
Tianjin, Dec. 2009.
[14] S. Panda, N.P. Padhy, "Application of genetic algorithm for PSS and
FACTS based controller design", Inte. Jou. of Com. Met., Vol.5, No.4,
pp.607-620, 2008.
[15] R. Pradhan, S. Panda, "Application of Genetic Algorithm based PSS for
two-area AGC system in deregulated scenario", IEEE/NABIC, pp.1207-
1212, Coimbatore, Dec. 2009.
[16] S.S. Lee, S.Y. Li, J.K. Park, "Nonlinear adaptive back-stepping
controller design for power system stabilizer in multi-machine power
systems", IEEE/AACC, pp.2504-2509, Washington USA, June 2008.
[17] Z. Jiang, "Design of a nonlinear power system stabilizer using
synergetic control theory", Elec. Pow. Sys. Res., Vol.79, No.6, pp/855-
862, June 2009.
[18] K.D. Young, V.I. Utkin, U. Ozguner, "A control engineer's guide to
sliding mode control", IEEE Trans. on Con. Sys. Tec., Vol.7, No.3,
pp.328-342, Aug. 2002.
[19] Y. Lee, Y.B. Shtessel, "Comparison of a feedback linearization controller
and sliding mode controllers for a permanent magnet stepper motor",
IEEE/SSST, pp.258-262, Baton Rouge, Mar./April 1996.
@article{"International Journal of Electrical, Electronic and Communication Sciences:52428", author = "Hossein Shahinzadeh and Ladan Darougaran and Ebrahim Jalili Sani and Hamed Yavari and Mahdi Mozaffari Legha", title = "Design of Power System Stabilizer Based on Sliding Mode Control Theory for Multi- Machine Power System", abstract = "This paper present a new method for design of power
system stabilizer (PSS) based on sliding mode control (SMC)
technique. The control objective is to enhance stability and improve
the dynamic response of the multi-machine power system. In order to
test effectiveness of the proposed scheme, simulation will be carried
out to analyze the small signal stability characteristics of the system
about the steady state operating condition following the change in
reference mechanical torque and also parameters uncertainties. For
comparison, simulation of a conventional control PSS (lead-lag
compensation type) will be carried out. The main approach is
focusing on the control performance which later proven to have the
degree of shorter reaching time and lower spike.", keywords = "Power system stabilizer (PSS), multi-machine power
system, sliding mode control", volume = "6", number = "2", pages = "167-6", }