Authors: M. H. Moradi, S. M. Moosavi, A. R. Reisi

Abstract:

The main objective of this paper is to investigate the enhancement of power system stability via coordinated tuning of Power System Stabilizers (PSSs) in a multi-machine power system. The design problem of the proposed controllers is formulated as an optimization problem. Chaotic catfish particle swarm optimization (C-Catfish PSO) algorithm is used to minimize the ITAE objective function. The proposed algorithm is evaluated on a two-area, 4- machines system. The robustness of the proposed algorithm is verified on this system under different operating conditions and applying a three-phase fault. The nonlinear time-domain simulation results and some performance indices show the effectiveness of the proposed controller in damping power system oscillations and this novel optimization algorithm is compared with particle swarm optimization (PSO).

Keywords: Power system stabilizer, C-Catfish PSO, ITAE objective function, Power system control, Multi-machine power system

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1080000

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References:

[1] Basler MJ, Schaefer RC. Understanding power system stability. IEEE Trans Indus Appl 2008;44:463-74.
[2] Andreoiu A. On power systems stabilizers: genetic algorithm based tuning and economic worth as ancillary services. Ph.D. Thesis. Chalmers University; 2004.
[3] Xia D, Heydt GT. Self-tuning controller for generator excitation control. IEEE trans PAS 1983;102:1877-85.
[4] Cao Y, jiang L, Cheng S, Chen D, Malik OP, Hope GS. A nonlinear variable structure stabilizer for power system stability. IEEE Trans EC 1994;9(3):489-95.
[5] Abido MA, Abdel-Majid YL. A hybrid Neuro-fuzzy power system stabilizer for multimachine power systems. IEEE Trans PWRS 1998;13(4):1323-30.
[6] Fraile-Ardanuy J, Zufiria PJ. Design and comparison of adaptive power system stabilizers based on neural fuzzy networks and genetic algorithms. Neurocomputing 2007;70:2902-12
[7] Segal R, Sharma A, Kothari ML. A self-tuning power system stabilizer based on artificial neural network. Elect Power Energy Syst 2004;26:423-30.
[8] Hardiansyah FS, Furuya S, Irisawa J. A robust H ¥ power system stabilizer design using reduced-order models. Elect Power Energy Syst 2006;28:21-8.
[9] Abdel-Magid YL, Abido MA, AI-Baiyat S, Mantawy AH. Simultaneous stabilization of multimachine power systems via genetic algorithms. IEEE Trans Power Syst 1999;14(4):1428-39.
[10] Abido MA, Abdel-Magid YL. Hybridizing rule-based power system stabilizers with genetic algorithms. IEEE Trans Power Syst 1999;14(2):600-7.
[11] Zhang P, Coonick AH. Coordinated synthesis of PSS parameters in multimachine power systems using the method of inequalities applied to genetic algorithms. IEEE Trans Power Syst 2000;15(2):811-6.
[12] Abdel-Magid YL, Abido MA. Optimal multiobjective design of robust power system stabilizers using genetic algorithms. IEEE Trans Power Syst 2003;18(3):1125-32.
[13] Abdel-Magid YL, Abido MA, Mantawy AH. Robust tuning of power system stabilizers in multimachine power systems. IEEE Trans Power Syst 2000;15(2):735-40.
[14] Abido MA. Robust design of multimachine power system stabilizers using simulated annealing. IEEE Trans Energy Convers 2003;15(3):297-304.
[15] Abido MA, Abdel-Magid YL. Optimal design of power system stabilizers using evolutionary programming. IEEE Trans Energy Convers 2002;17(4):429-36.
[16] Mishra S, Tripathy M, Nanda J. Multi-machine power system stabilizer design by rule based bacteria foraging. Electr Power Syst Res 2007;77:1595-607.
[17] Ricardo V. de Oliveira, Rodrigo A. Ramos, Newton G. Bretas. An algorithm for computerized automatic tuning of power system stabilizers. Control Engineering Practice 18 (2010) 45-54
[18] H. Shayeghi, H.A. Shayanfar, A. Safari, R. Aghmasheh. A robust PSSs design using PSO in a multi-machine environment. Energy Conversion and Management 51 (2010) 696-702
[19] Fukuyama, Y. (1999). A particle swarm optimization for reactive power and voltage control considering voltage stability. Proceedings of IEEE international conference on intelligent system applications to power systems (ISAP), Rio de Janeiro.
[20] Shayeghi H, Jalili A, Shayanfar HA. Multi-stage fuzzy load frequency control using PSO. Energy Convers Manage 2008;49:2570-80.
[21] Kennedy J, Eberhart R, Shi Y. Swarm intelligence. San Francisco: Morgan Kaufmann Publishers; 2001.
[22] dos Santos Coelho, V.C. Mariani, A novel chaotic particle swarm optimization approach using Hénon map and implicit filtering local search for economic load dispatch, Chaos, Solitons and Fractals 39 (2009) 510-518.
[23] Y. Shi and R.C. Eberhart, Empirical study of particle swarm optimization, in: Proceedings of Congress on Evolutionary Computation, Washington, DC, 2002, pp. 1945-1949.
[24] H. Gao, Y. Zhang, S. Liang, D. Li, A new chaotic algorithm for image encryption, Chaos, Solitons and Fractals 29 (2006) 393-399.
[25] D. Kuo, Chaos and its computing paradigm, IEEE Potentials Magazine 24 (2005) 13-15.
[26] Li-Yeh Chuang, Sheng-Wei Tsai, Cheng-Hong Yang, Chaotic catfish particle swarm optimization for solving global numerical optimization problems, Applied Mathematics and Computation 217 (2011) 6900- 6916
[27] Kundur P. Power system stability and control. New York: McGraw Hill; 1994.
[28] Sadikovic R. Damping controller design for power system oscillations. Zurich: Internal Report; 2004.
[29] Mishra S. Neural network based adaptive UPFC for improving transient stability performance of power system. IEEE Trans Neural Networks 2006;17(2):461-70.
[30] Nguyen TT, Gianto R. Optimisation based control coordination of PSSs and FACTS devices for optimal oscillations damping in multi-machine power system. IEE Proc Gener Transm Distrib 2007;1(4):564-73.
[31] Shayeghi H, Shayanfar HA, Jalili A. Multi stage fuzzy PID power system automatic generation controller in deregulated environments. Energy Convers Manage 2006;47:2829-45.