Araştırma Makalesi
BibTex RIS Kaynak Göster
Yıl 2015, Cilt: 15 Sayı: 1, 1855 - 1862, 16.11.2015

Öz

Kaynakça

  • Anderson, P.M., and Fouad, A. A. Power System Control and Stability, Ames, IA: Iowa State Univ. Press, 1977.
  • Kundur, P., Power System Stability and Control, New York: McGraw-Hill, 1994.
  • Hsu, Y. Y., and Hsu, C. Y. "Design of a Proportional- Integral Power System Stabilizer," IEEE Trans on Power Syst, Vol.1, No.2, pp.46-52, May 1986.
  • Kundur, P., Klein, M., Rogers, G.J., Zywno, M.S. "Application enhancement of overall system stability," IEEE Trans on Power Syst, Vol.4, No.2, pp.614-626, May 1989. for
  • Gibbard, M.J. "Robust design of fixed-parameter power system stabilizers over a wide range of operating conditions," IEEE Trans on Power Syst, Vol.6, No.2, pp.794-800, May 1991.
  • Abido, M. A., and Abdel-Magid, Y. L. "Coordinated design of a PSS and an SVC-based controller to enhance power system stability," Int. J. Electr. Power Energy Syst., Vol. 25, pp. 695-704, 2003.
  • Abdel-Magid, Y.L., Abido, M.A., Al-Baiyat, S., Mantawy, A. H. "Simultaneous stabilization of multi-machine power systems via genetic algorithms," IEEE Trans on Power Syst, Vol.14, No.4, pp.1428-1439, November 1999.
  • Abdel-Magid, Y.L., Abido, M.A. "Optimal multi-objective design of robust power system stabilizers using genetic algorithms," IEEE Trans on Power Syst, Vol.18, No.3, pp.1125-1132, August 2003.
  • Abido, M.A. "Robust design of multi-machine power system stabilizers using simulated annealing," IEEE Trans on Energy Convers, Vol.15, No.3, pp.297-304, September 2000.
  • Abido, M. A., Abdel-Magid, Y. L. "Optimal Design of Power System Stabilizers Using Evolutionary Programming," IEEE Trans on Energy Convers, Vol.17, No.4, pp.429-436, December 2002.
  • Sebaa, K., Boudour, M. "Optimal locations and tuning of robust power system stabilizer using genetic algorithms," Electr Power Syst Res, Vol. 79, No.2, pp.406-416, February 2009.
  • Shayeghi, H., Shayanfar, H. A., Jalilzadeh, S., Safari A. "Multi-machine power system stabilizers design using chaotic optimization algorithm," Energy Convers Manage, Vol.51, No.7, pp.1572-1580, July 2010.
  • Mishra, S., Tripathy, M., Nanda, J. "Multi-machine power system stabilizer design by rule based bacteria foraging," Electr Power Syst Res, Vol.77, No.12, pp.1595-1607, October 2007.
  • Khodabakhshian, A., Hemmati, R. "Multi-machine power system stabilizer design by using cultural algorithms, " Int J Electr Power Energy Syst, Vol.44, No.1, pp. 571-580, January 2013.
  • Mary Linda, M., Kesavan Nair, N. "A new-fangled adaptive mutation breeder genetic optimization of global multi- machine power system stabilizer," Int J Electr Power Energy Syst, Vol.44, No.1, pp.249-258, January 2013.
  • Kennedy, J. and Eberhart, R. C. "Particle swarm optimization," Proceedings of the IEEE International Conference on Neural Networks, Vol.4, pp.1942-1948, November/December 1995.
  • Al-Awami, A.T., Abdel-Magid, Y. L., Abido, M. A. "Simultaneous stabilization of power system using UPFC- based controllers," Elect Power Comp Syst, Vol.34, No.9, pp.941-959, August 2006.
  • Panda, S., Padhy, N. P., Patel, R. N. "Power-system Stability Improvement by PSO Optimized SSSC-based Damping Controller," Elect Power Comp Syst, Vol.36, No.5, pp.468-490, 2008.
  • Sauer, P.W., Pai, M.A. Power system Dynamics and Stability, Prentice Hall, 1998.
  • deMello, F. Concordia C. "Concepts of Synchronous Machine Stability as Affected by Excitation Control," IEEE Trans. PAS, Vol.88, pp.316-329, 1969.
  • Kennedy, J., Eberhart, R., Shi, Y. Swarm intelligence, San Francisco: Morgan Kaufmann Publishers, 2001.
  • Ratnaweera, A., Halgamuge, S.K., Watson, H.S. “Self organizing hierarchical particle swarm optimizer with time varying acceleration coefficients,”, IEEE Trans Evolut Comput, Vol.8, no.3, pp.240-255, June 2004.
  • Hsu, Y.Y., Chen, C.L. “Identification of Optimum Location for Stabilizer Applications Using Participation Factors,” Generation, Transmission and Distribution, IEE Proceedings C , Vol.134, no.3, pp.238-244, May 1987.
  • Dorf, R.C. and Bishop, R.H. Modern Control Systems, Prentice Hall, 2010.
  • Coley, D. A. An introduction to genetic algorithms for scientists and engineers, World Scientific Press, 1999.
  • Shayeghi, H., Shayanfar, H.A., Jalilzadeh, S., Safari, A. “TCSC robust damping controller design based on particle swarm optimization for a multi-machine power system,” Energy Convers Manage, Vol.51, pp. 1873- 1882, October 2010. APPENDIX A
  • Data for the studied three-machine nine-bus power
  • system. All data are in pu unless specified otherwise.
  • For further information, see Ref. [19]. H1 23.64, H 2 6.4, H 3 3.01, D 1 0, D2 D3 1dx x1qq x2qq x3qq 0.0969, 0.8645, 1.2578, 0.0608, x1dd 0.1198, x2dd 0.1813, x3dd 8.96, do do1 T1 Exciter: KA 1A 5.89 T3 2A 100, T 3A KA KA 1A 0.05 T2A T3A APPENDIX B
  • Based on the mechanism of the natural selection
  • and survival of the fittest, genetic algorithms are
  • considered as stochastic search methods [25].
  • Moreover, they integrate function evaluation with
  • randomized and/or well-structured exchange of
  • information amongst the solutions in order to achieve
  • the global optimum point. The architecture of the GA
  • implementation may be divided into following three
  • basic steps: initial population generation, fitness
  • evaluation and genetic operations. The GA control
  • parameters, like population size, mutation probability
  • and crossover probability, are chosen and a first
  • population of the binary strings of the finite length is
  • randomly generated [26]. Given a random initial
  • population GA operates in cycles called generations, as follows [25]:
  • Every population member is assessed by employing a fitness function.
  • The population undergoes reproduction through several
  • iterations. At least one parent is selected stochastically.
  • Still, strings possessing higher fitness values would have
  • higher probability of contributing an offspring.
  • In order to produce offspring, genetic operators, like
  • crossover and mutation, are assigned to parents.
  • The offspring are placed in the population and the procedure is rerun.
  • The time-domain simulation is carried out and the
  • fitness function, as shown in (15), is optimized so as to
  • arrive at the optimal set of controller parameters. While
  • applying GA, parameters' figure must be indicated.
  • Optimization is terminated by the generations' pre-specified
  • figure for the genetic algorithm.

PSO BASED PSS DESIGN FOR TRANSIENT STABILITY ENHANCEMENT

Yıl 2015, Cilt: 15 Sayı: 1, 1855 - 1862, 16.11.2015

Öz

In this paper, optimal tuning the parameters of a power system stabilizer (PSS) controller for the power system transient stability enhancement is introduced. The design problem of the proposed PSS is converted to an optimization problem with the time-domain based objective function which is solved by using particle swarm optimization (PSO) technique with a robust ability in order to find the most promising results. The dynamic performance PSS controller is evaluated on the basis of a multi-machine power system exposed to the diverse disturbances by comparison with the genetic algorithm-based damping controller. By virtue of the nonlinear time-domain simulation and some performance indices studies, the performance of the proposed PSS controller is tested and observed.   The results show that the tuned PSO based PSS damping controller by the proposed fitness function has an excellent capability in damping power system low frequency oscillations, as well as it significantly improves the dynamic stability of the power systems. In addition, the results reveal that the performance of the designed controller is better than the genetic algorithm based stabilizer.

Kaynakça

  • Anderson, P.M., and Fouad, A. A. Power System Control and Stability, Ames, IA: Iowa State Univ. Press, 1977.
  • Kundur, P., Power System Stability and Control, New York: McGraw-Hill, 1994.
  • Hsu, Y. Y., and Hsu, C. Y. "Design of a Proportional- Integral Power System Stabilizer," IEEE Trans on Power Syst, Vol.1, No.2, pp.46-52, May 1986.
  • Kundur, P., Klein, M., Rogers, G.J., Zywno, M.S. "Application enhancement of overall system stability," IEEE Trans on Power Syst, Vol.4, No.2, pp.614-626, May 1989. for
  • Gibbard, M.J. "Robust design of fixed-parameter power system stabilizers over a wide range of operating conditions," IEEE Trans on Power Syst, Vol.6, No.2, pp.794-800, May 1991.
  • Abido, M. A., and Abdel-Magid, Y. L. "Coordinated design of a PSS and an SVC-based controller to enhance power system stability," Int. J. Electr. Power Energy Syst., Vol. 25, pp. 695-704, 2003.
  • Abdel-Magid, Y.L., Abido, M.A., Al-Baiyat, S., Mantawy, A. H. "Simultaneous stabilization of multi-machine power systems via genetic algorithms," IEEE Trans on Power Syst, Vol.14, No.4, pp.1428-1439, November 1999.
  • Abdel-Magid, Y.L., Abido, M.A. "Optimal multi-objective design of robust power system stabilizers using genetic algorithms," IEEE Trans on Power Syst, Vol.18, No.3, pp.1125-1132, August 2003.
  • Abido, M.A. "Robust design of multi-machine power system stabilizers using simulated annealing," IEEE Trans on Energy Convers, Vol.15, No.3, pp.297-304, September 2000.
  • Abido, M. A., Abdel-Magid, Y. L. "Optimal Design of Power System Stabilizers Using Evolutionary Programming," IEEE Trans on Energy Convers, Vol.17, No.4, pp.429-436, December 2002.
  • Sebaa, K., Boudour, M. "Optimal locations and tuning of robust power system stabilizer using genetic algorithms," Electr Power Syst Res, Vol. 79, No.2, pp.406-416, February 2009.
  • Shayeghi, H., Shayanfar, H. A., Jalilzadeh, S., Safari A. "Multi-machine power system stabilizers design using chaotic optimization algorithm," Energy Convers Manage, Vol.51, No.7, pp.1572-1580, July 2010.
  • Mishra, S., Tripathy, M., Nanda, J. "Multi-machine power system stabilizer design by rule based bacteria foraging," Electr Power Syst Res, Vol.77, No.12, pp.1595-1607, October 2007.
  • Khodabakhshian, A., Hemmati, R. "Multi-machine power system stabilizer design by using cultural algorithms, " Int J Electr Power Energy Syst, Vol.44, No.1, pp. 571-580, January 2013.
  • Mary Linda, M., Kesavan Nair, N. "A new-fangled adaptive mutation breeder genetic optimization of global multi- machine power system stabilizer," Int J Electr Power Energy Syst, Vol.44, No.1, pp.249-258, January 2013.
  • Kennedy, J. and Eberhart, R. C. "Particle swarm optimization," Proceedings of the IEEE International Conference on Neural Networks, Vol.4, pp.1942-1948, November/December 1995.
  • Al-Awami, A.T., Abdel-Magid, Y. L., Abido, M. A. "Simultaneous stabilization of power system using UPFC- based controllers," Elect Power Comp Syst, Vol.34, No.9, pp.941-959, August 2006.
  • Panda, S., Padhy, N. P., Patel, R. N. "Power-system Stability Improvement by PSO Optimized SSSC-based Damping Controller," Elect Power Comp Syst, Vol.36, No.5, pp.468-490, 2008.
  • Sauer, P.W., Pai, M.A. Power system Dynamics and Stability, Prentice Hall, 1998.
  • deMello, F. Concordia C. "Concepts of Synchronous Machine Stability as Affected by Excitation Control," IEEE Trans. PAS, Vol.88, pp.316-329, 1969.
  • Kennedy, J., Eberhart, R., Shi, Y. Swarm intelligence, San Francisco: Morgan Kaufmann Publishers, 2001.
  • Ratnaweera, A., Halgamuge, S.K., Watson, H.S. “Self organizing hierarchical particle swarm optimizer with time varying acceleration coefficients,”, IEEE Trans Evolut Comput, Vol.8, no.3, pp.240-255, June 2004.
  • Hsu, Y.Y., Chen, C.L. “Identification of Optimum Location for Stabilizer Applications Using Participation Factors,” Generation, Transmission and Distribution, IEE Proceedings C , Vol.134, no.3, pp.238-244, May 1987.
  • Dorf, R.C. and Bishop, R.H. Modern Control Systems, Prentice Hall, 2010.
  • Coley, D. A. An introduction to genetic algorithms for scientists and engineers, World Scientific Press, 1999.
  • Shayeghi, H., Shayanfar, H.A., Jalilzadeh, S., Safari, A. “TCSC robust damping controller design based on particle swarm optimization for a multi-machine power system,” Energy Convers Manage, Vol.51, pp. 1873- 1882, October 2010. APPENDIX A
  • Data for the studied three-machine nine-bus power
  • system. All data are in pu unless specified otherwise.
  • For further information, see Ref. [19]. H1 23.64, H 2 6.4, H 3 3.01, D 1 0, D2 D3 1dx x1qq x2qq x3qq 0.0969, 0.8645, 1.2578, 0.0608, x1dd 0.1198, x2dd 0.1813, x3dd 8.96, do do1 T1 Exciter: KA 1A 5.89 T3 2A 100, T 3A KA KA 1A 0.05 T2A T3A APPENDIX B
  • Based on the mechanism of the natural selection
  • and survival of the fittest, genetic algorithms are
  • considered as stochastic search methods [25].
  • Moreover, they integrate function evaluation with
  • randomized and/or well-structured exchange of
  • information amongst the solutions in order to achieve
  • the global optimum point. The architecture of the GA
  • implementation may be divided into following three
  • basic steps: initial population generation, fitness
  • evaluation and genetic operations. The GA control
  • parameters, like population size, mutation probability
  • and crossover probability, are chosen and a first
  • population of the binary strings of the finite length is
  • randomly generated [26]. Given a random initial
  • population GA operates in cycles called generations, as follows [25]:
  • Every population member is assessed by employing a fitness function.
  • The population undergoes reproduction through several
  • iterations. At least one parent is selected stochastically.
  • Still, strings possessing higher fitness values would have
  • higher probability of contributing an offspring.
  • In order to produce offspring, genetic operators, like
  • crossover and mutation, are assigned to parents.
  • The offspring are placed in the population and the procedure is rerun.
  • The time-domain simulation is carried out and the
  • fitness function, as shown in (15), is optimized so as to
  • arrive at the optimal set of controller parameters. While
  • applying GA, parameters' figure must be indicated.
  • Optimization is terminated by the generations' pre-specified
  • figure for the genetic algorithm.
Toplam 58 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Mühendislik
Bölüm Makaleler
Yazarlar

Serdar Ekinci

Aysen Demiroren Bu kişi benim

Yayımlanma Tarihi 16 Kasım 2015
Yayımlandığı Sayı Yıl 2015 Cilt: 15 Sayı: 1

Kaynak Göster

APA Ekinci, S., & Demiroren, A. (2015). PSO BASED PSS DESIGN FOR TRANSIENT STABILITY ENHANCEMENT. IU-Journal of Electrical & Electronics Engineering, 15(1), 1855-1862.
AMA Ekinci S, Demiroren A. PSO BASED PSS DESIGN FOR TRANSIENT STABILITY ENHANCEMENT. IU-Journal of Electrical & Electronics Engineering. Kasım 2015;15(1):1855-1862.
Chicago Ekinci, Serdar, ve Aysen Demiroren. “PSO BASED PSS DESIGN FOR TRANSIENT STABILITY ENHANCEMENT”. IU-Journal of Electrical & Electronics Engineering 15, sy. 1 (Kasım 2015): 1855-62.
EndNote Ekinci S, Demiroren A (01 Kasım 2015) PSO BASED PSS DESIGN FOR TRANSIENT STABILITY ENHANCEMENT. IU-Journal of Electrical & Electronics Engineering 15 1 1855–1862.
IEEE S. Ekinci ve A. Demiroren, “PSO BASED PSS DESIGN FOR TRANSIENT STABILITY ENHANCEMENT”, IU-Journal of Electrical & Electronics Engineering, c. 15, sy. 1, ss. 1855–1862, 2015.
ISNAD Ekinci, Serdar - Demiroren, Aysen. “PSO BASED PSS DESIGN FOR TRANSIENT STABILITY ENHANCEMENT”. IU-Journal of Electrical & Electronics Engineering 15/1 (Kasım 2015), 1855-1862.
JAMA Ekinci S, Demiroren A. PSO BASED PSS DESIGN FOR TRANSIENT STABILITY ENHANCEMENT. IU-Journal of Electrical & Electronics Engineering. 2015;15:1855–1862.
MLA Ekinci, Serdar ve Aysen Demiroren. “PSO BASED PSS DESIGN FOR TRANSIENT STABILITY ENHANCEMENT”. IU-Journal of Electrical & Electronics Engineering, c. 15, sy. 1, 2015, ss. 1855-62.
Vancouver Ekinci S, Demiroren A. PSO BASED PSS DESIGN FOR TRANSIENT STABILITY ENHANCEMENT. IU-Journal of Electrical & Electronics Engineering. 2015;15(1):1855-62.