PERFORMANCE IMPROVEMENT OF MINIMAX OPTIMIZED PI CONTROLLER-BASED DC DRIVE SYSTEM WITH ACTUATOR SATURATION

Yakhelef Yassine and Boulouh Messaoud

References

1. [1] H. Liang, W. Ning, and Z. Jin-Hui, Multiobjective optimizationfor controller design: Brief paper, Acta Automatica Sinica,34(4), 2008, 472–477.
2. [2] D.B. Ender, Process control performance, not as good as youthink, Control Engineering, 40, 1993, 180–190.
3. [3] K.J. Astrom and T. Hagglund, PID controllers: Theory, designand tuning, 2nd ed. (Research Triangle Park, NC: InstrumentSociety of America, 1995).
4. [4] N. Peri´c, I. Branica, and I. Petrovi´c, Modification and appli-cation of auto-tuning PID controller, Proc. 8th IEEE Mediter-ranean Conf. on Control and Automation (MED 2000), RioPatras, Greece, 2000.
5. [5] K.J. Astrom and T. Hagglund, The future of PID control,Control Engineering Practice (Elsevier), Pergamon, 9, 2001,1163–1175.
6. [6] K.H. Ang, G.C.Y. Chong, and Y. Li, PID control system,analysis, design, and technology. IEEE Transactions on ControlSystems Technology, 13(4), 2005, 559–576.
7. [7] X. Min, S. Yuan, and C. Wen-Jian, Receding horizon opti-mization approach to PID controller parameters auto-tuning,ACTA Automatica Sinica, 31(3), 2005, 459–463.
8. [8] A. O’Dwyer, PI and PID controller tuning rules for timedelay processes: A summary, Technical Report, ed. 1, DublinInstitute of Technology, Ireland, 2000.
9. [9] J.G. Ziegler and N.B. Nichols, Optimum settings for automaticcontrollers, Transactions on ASME, 64, 1942, 759–768.
10. [10] D. Xue, Y.Q. Chen, and D.P. Atherton, PID controller design,in, linear feedback control (Society for Industrial and AppliedMathematics, 2007), 183–235. www.siam.org/catalog.
11. [11] K.J. Astrom and R.M. Murray, Feedback systems: An intro-duction to scientists and engineer (NJ: Princeton UniversityPress, 2008).
12. [12] K.J Astrom and T. Hagglund, Revising the Ziegler–Nicholsstep response method for PID control, Journal of ProcessControl, 14, 2004, 635–650.
13. [13] Y.Q. Chen, C.H. Hu, and K.L. Moore, Relay feedback tuningof PID controllers with iso-damping property, Proc. 42nd IEEEConf. on Decision and Control, Maui, Hawaii, 2003, 2180–2185.
14. [14] R.C. Chang, S.H. Shen, and C.C. Yu, Derivation of transferfunction from relay feedback systems, Industrial and Engi-neering Chemistry Research, 31(3), 1992, 855–860.
15. [15] D.E. Revera, M. Morari, and S. Skogestad, Internal modelcontrol for PID controller design, Industrial and EngineeringChemistry Process Design and Development, 25(1), 1986,252–265.
16. [16] M. Shamsuzzoha and M. Lee, A simple analytical controllerdesign for integrating and first order unstable time delay process(School of Chemical Engineering and Technology, YeungnamUniversity, Korea, 2006).
17. [17] R. Vilanova, IMC based PID design: tuning guide lines andautomatic tuning, Journal of Process Control, 8, 2008, 61–70.
18. [18] N.J. Killingsworth and M. Krstic, PID tuning using extremumseeking: Online model free performance optimization, IEEEControl System Magazine, 2006, 70–79.
19. [19] N.J. Killingsworth and M. Krstic, Auto-tuning of PID controllervia extremum seeking, American Control Conference, Portland,OR, 2005, 2251–2256.
20. [20] O. Lequin et al., Iterative feedback tuning of PID parameters:comparison with classical tuning rules, Elsevier Preprint, 2002.
21. [21] H. Panagopoulos, K.J. Astrom, and T. Hagglund, Design ofPID controllers based on nonconvex optimization, Automatica,34(5), 1998, 585–601.
22. [22] H. Panagopoulos, K.J. Astrom, and T. Hagglund, Designof PID controllers based on constrained optimization, Proc.American Control Conference, San Diego, CA, 1999.277
23. [23] W. Tan, H.J. Marquez, and T. Chen, Performance assessmentof PID controllers, Control and Intelligent Systems, 32(3),2004. DOI: 10.2316/Journal.201.2004.3.201-1309.
24. [24] L. Carotenuto, P. Pugliese, and Ya.D. Sergeyev, Maximizingperformance and robustness of PI and PID controllers by globaloptimization, Control and Intelligent Systems, 34(3), 2006.DOI: 10.2316/Journal.201.2006.3.201-1558.
25. [25] M. Kushwah and A. Patra, Tuning PID controller for speedcontrol of dc motor using soft computing techniques – a review,Advance in Electronic and Electric Engineering, 4(2), 2014,141–148.
26. [26] V. Shrivastva and R. Singh, Performance analysis of speedcontrol of direct current (dc) motor using traditional tuningcontroller, International Journal of Emerging Technology andAdvanced Engineering, 4(5), 2014, 119–125.
27. [27] M.S. Mohiuddin and M. Alam, Performance analysis of fuzzylogic based speed control of dc motor, IOSR Journal ofElectrical and Electronics Engineering (IOSR-JEEE), 7(4),2013, 17–24.
28. [28] F. Cupertino, D. Naso, L. Salvatore, and B. Turchiano, De-sign of cascaded controllers for DC drives using evolutionaryalgorithms, IEEE, 2, 2002, 1255–1260.
29. [29] F. Gurbuz and E. Akpinar, Stability analysis of a closed-loopcontrol for a pulse width modulated DC motor drive, TurkishJournal of Electrical Engineering, 10(3), 2002, 427–438.
30. [30] L.V. Akimov, V.T. Dolbnia, and V.I. Kolotilo, Electric DCdrive control systems with state observers (Ukraine: KHSPU(Kharkov State Polytechnic University), 1998).
31. [31] MATLAB/SIMULINK, V 7.3 (R2009a), The MathWorks, Inc.,2009.
32. [32] M.T. Jensen, A new look at solving Mini-Max problems, 4-ThMetaheuristics International Conference, MIC’2001, Porto,Portugal, 2001.
33. [33] J.V. Neumann, On the theory of games, Mathematische An-nalen, 100, 1928, 295–320.
34. [34] A.I. Gull, Minimax optimization of PI regulator parametersto maximize the stability margin of electromechanical systemswith increased Q factor, Russian Electrical Engineering, 70(5),1999, 39–44.
35. [35] A.I. Gull and M. Boulouh, Complex criterion of control qualityfor conditionally stable electromechanical systems, Journal ofRussian Academy of Science (Elektrichestvo), 12, Moscow,Russia, 2006, 36–39.
36. [36] A.I. Gull and M. Boulouh, Choice of criteria and optimizationprinciple of PI regulator of electromechanical system, Trans-action Vestnik of Polytechnic State University of Kharkov, 21,Kharkov, Ukraine, 1998, 104–108.
37. [37] MATLAB Optimization Toolbox, V 4.2 (R2009a), TheMathWorks, Inc., 2009.
38. [38] X.L. Li, J.G. Park, and H.B. Shin, Comparison and evaluationof anti windup PI controllers, Journal of Power Electronics,11(1), 2011, 45–50.
39. [39] Y. LI, K.H. Ang, and G.C.Y. Chong, PID control systemanalysis and design, IEEE Control Systems Magazine, 26(1),2006, 32–41.
40. [40] A. Visioli, Advances in industrial control: Practical PID control(London: Springer Verlag), 2006.
41. [41] H. Markaroglu, M. Guzelkaya, I. Eksin, and E. Yesil, Trackingtime adjustment in back calculation anti wind up scheme, Proc.20th European Conf. on Modeling and Simulation (ECMS),Wolfgang Buritzky, Alessandra Orsoni, Richard Zobel, 2006.
42. [42] J. Espina, A. Arias, J. Balcells, and C. Ortega, Speed anti-windup PI strategies review for field oriented control of perma-nent magnet synchronous machines, 6th International Conf.Workshop on Compatibility and Power Electronics, CPE2009,2009.
43. [43] Y. Peng, D. Vrancic, and R. Hanus, Anti windup, bump-less and conditioned transfer techniques for PID controllers,IEEE Control Systems, 1996, 48–57. 0272-1708/96/$05.0001996IEEE.

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• Abstract
• DOI: 10.2316/Journal.201.2014.4.201-2469
• From Journal (201) Mechatronic Systems and Control (formerly Control and Intelligent Systems) - 2014

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