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Abstract

This paper proposes a self-tuned proportional-integral-derivative (PID) controller for a class of uncertain continuous-time multi-input multi-output nonlinear dynamic systems. Within this scheme, the PID controller is employed to approximate an unknown ideal controller that can achieve control objectives. The three PID control gains are adjustable parameters and they are updated online with a stable adaptation mechanism designed to minimize the error between the unknown ideal controller and the used PID controller. The proposed approach can be regarded as a simple and effective model-free control because the mathematical model of the system is assumed unknown. The stability analysis of the closed-loop system is performed using a Lyapunov approach. It is proved that all signals in the closed-loop system are uniformly ultimately bounded and that the tracking error can be made to converge to zero in the absence of approximation errors. The effectiveness of the proposed adaptive PID control is demonstrated in simulation.

Keywords

Adaptation mechanism ideal controller MIMO nonlinear systems model-free control PID control

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References

Ahn

Truong

(2009) Online tuning fuzzy PID controller using robust extended kalman filter. Journal of Process Control 19(6): 1011–1023.

Almeida

Reis

LLN

Bezerra

LDS

Lima

SEU

(2006) A MIMO fuzzy logic autotuning PID controller: method and application. In: Abraham

Baets

Köppen

Nickolay

(eds) Applied Soft Computing Technologies: The Challenge of Complexity Berlin: Springer 569–580.

Arruda

Swiech

Delgado

Neves-Jr

(2008) PID control of MIMO process based on rank niching genetic algorithm. Applied Intelligence 29(3): 290–305.

Astrom

Hagglund

(1995) PID Controllers: Theory Design and Tuning North Carolina: Instrument Society of America.

Bagis

(2007) Determination of the PID controller parameters by modified genetic algorithm for improved performance. Journal of Information Science and Engineering 23(5): 1469–1480.

Chaikovskii

Yadykin

(2009) Optimal tuning of PID controllers for MIMO bilinear plants. Automation and Remote Control 70(1): 33–42.

Chang

(2007) A multi-crossover genetic approach to multivariable PID controllers tuning. Expert Systems with Applications 33(3): 620–626.

Chang

Yan

(2005) Adaptive robust PID controller design based on a sliding mode for uncertain chaotic systems. Chaos, Solitons and Fractals 26(1): 167–175.

Chang

Hwang

Hsieh

(2002) A self-tuning PID control for a class of nonlinear systems based on the lyapunov approach. Journal of Process Control 12(2): 233–242.

10.

Coelho

LDS

(2009) Tuning of PID controller for an automatic regulator voltage system using chaotic optimization approach. Chaos, Solitons and Fractals 39(4): 1504–1514.

11.

Hjalmarsson

Gevers

Gunnarsson

Lequin

(1998) Iterative feedback tuning: theory and applications. IEEE Control Systems Magazine 18(4): 26–41.

12.

Ioannou

Sun

(1996) Robust Adaptive Control Englewood Cliffs, New Jersey: Prentice Hall.

13.

Iruthayarajan

Baskar

(2009) Evolutionary algorithms based design of multivariable PID controller. Expert Systems with Applications 36(5): 9159–9167.

14.

Khalil

(1996) Nonlinear Systems2. Englewood Cliffs, New Jersey: Prentice-Hall.

15.

Labiod

Guerra

(2007) Direct adaptive fuzzy control for a class of MIMO nonlinear systems. International Journal of Systems Science 38(8): 665–675.

16.

Lequin

Gevers

Mossberg

Bosmans

Triest

(2003) Iterative feedback tuning of PID parameters: comparison with classical tuning rules. Control Engineering Practice 11(9): 1023–1033.

17.

Mizumoto

Hirahata

Ohdaira

Iwai

(2009) Adaptive PID controller design based on output feedback passivity for discrete-time nonlinear systems. Proceedings of the American Control Conference, St. Louis, MO, June 10-12, 4673–4679.

18.

Slotine

(1991) Applied Nonlinear Control Englewood Cliffs, New Jersey: Prentice Hall.

19.

Toscano

Lyonnet

(2009) Robust PID controller tuning based on the heuristic kalman algorithm. Automatica 45(9): 2099–2106.

20.

Yamamoto

Shah

(2004) Design and experimental evaluation of a multivariable self-tuning PID controller. In IEE Proceedings – Control Theory and Applications 151(5): 645–652.

21.

Chang

(2005) Fault tolerant control of multivariable processes using auto-Tuning PID controller. IEEE Transactions on Systems, Man, and Cybernetics 35(1): 32–43.

22.

Chang

(2007) A stable self-learningPID control for multivariable time varying systems. Control Engineering Practice 15(12): 1577–1587.

23.

Yusof

Omatu

(1993) A multivariable self-tuning PID controller. International Journal of Control 57(6): 1387–1403.

24.

Zhang

Zhuang

Wang

(2009) Self-organizing genetic algorithm based tuning of PID controllers. Information Sciences 179(7): 1007–1018.

25.

Zhu

Zhao

Guo

Yang

(2009) CAS algorithm-based optimum design of PID controller in AVR system. Chaos, Solitons and Fractals 42(2): 792–800.

26.

Ziegler

Nichols

(1942) Optimum settings for automatic controllers. Transactions of ASME 64: 759–768.

A stable self-tuning proportional-integral-derivative controller for a class of multi-input multi-output nonlinear systems

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