Design of distributed \(H_\infty\) fuzzy controllers with constraint for nonlinear hyperbolic PDE systems. (English) Zbl 1271.93098
Summary: This paper investigates the problem of designing a distributed \(H_\infty\) fuzzy controller with constraint for a class of nonlinear spatially distributed processes modeled by first-order hyperbolic partial differential equations (PDEs). The purpose of this paper is to design a distributed fuzzy state feedback controller such that the closed-loop PDE system is exponentially stable with a prescribed \(H_\infty\) performance of disturbance attenuation, while the control constraint is respected. Initially, a Takagi-Sugeno (T-S) hyperbolic PDE model is proposed to accurately represent the nonlinear PDE system. Then, based on the T-S fuzzy PDE model, a distributed \(H_\infty\) fuzzy controller design with constraint is developed in terms of a set of coupled differential/algebraic linear matrix inequalities (D/ALMIs) in space. Furthermore, a suboptimal distributed \(H_\infty\) fuzzy controller with constraint is proposed to minimize the level of attenuation. The finite difference method in space and the existing linear matrix inequality (LMI) optimization techniques are employed to approximately solve the suboptimal fuzzy control design problem. Finally, the proposed design method is applied to the distributed control of a nonlinear system described by two coupled first-order hyperbolic PDEs to illustrate its effectiveness.
MSC:
| 93C42 | Fuzzy control/observation systems |
| 93B36 | \(H^\infty\)-control |
| 93C20 | Control/observation systems governed by partial differential equations |
| 93C10 | Nonlinear systems in control theory |
Keywords:
\(H_\infty\) control; Takagi-Sugeno (T-S) models; spatially distributed processes; control constraint; exponential stability; linear matrix inequalities (LMIs)Software:
LMI toolboxReferences:
| [1] | Aksikas, I.; Winkin, J. J.; Dochain, D., Optimal LQ-feedback regulation of a nonisothermal plug flow reactor model by spectral factorization, IEEE Transactions on Automatic Control, 52, 7, 1179-1193 (2007) · Zbl 1366.93560 |
| [2] | Balas, M. J., Feedback control of linear diffusion processes, International Journal of Control, 29, 3, 523-534 (1979) · Zbl 0398.93027 |
| [3] | Bamieh, B.; Paganini, F.; Dahleh, M. A., Distributed control of spatially invariant systems, IEEE Transactions on Automatic Control, 47, 7, 1091-1107 (2002) · Zbl 1364.93363 |
| [4] | Boyd, S.; Ghaoui EI, L.; Feron, E.; Balakrishnan, V., Linear matrix inequalities in system and control theory (1994), SIAM: SIAM PA · Zbl 0816.93004 |
| [5] | Burden, R. L.; Faires, J. D., Numerical analysis (2000), Brooks/Cole: Brooks/Cole New York |
| [6] | Chen, B.-S.; Chang, Y.-T., Fuzzy state-space modeling and robust observer-based control design for nonlinear partial differential systems, IEEE Transactions on Fuzzy Systems, 17, 5, 1025-1043 (2009) |
| [7] | Christofides, P. D., Nonlinear and robust control of PDE systems: methods and applications to transport-reaction processes (2001), Birkhäuser: Birkhäuser Boston, MA · Zbl 1018.93001 |
| [8] | Christofides, P. D.; Daoutidis, P., Feedback control of hyperbolic PDE systems, AIChE Journal, 42, 11, 3063-3086 (1996) |
| [9] | Curtain, R. F., Finite-dimensional compensator design for parabolic distributed systems with point sensors and boundary input, IEEE Transactions on Automatic Control, 27, 1, 98-104 (1982) · Zbl 0477.93039 |
| [10] | Demetriou, M. A., Guidance of mobile actuator-plus-sensor networks for improved control and estimation of distributed parameter systems, IEEE Transactions on Automatic Control, 55, 7, 1570-1584 (2010) · Zbl 1368.93268 |
| [11] | Feng, G., Analysis and synthesis of fuzzy control systems: a model based approach (2010), CRC: CRC Boca Raton, FL · Zbl 1215.93076 |
| [12] | Fister, K. R., Optimal control of harvesting with boundary control in a predator-prey system, Applied Analysis, 77, 1-2, 11-28 (2001) · Zbl 1014.92040 |
| [13] | Gahinet, P.; Nemirovskii, A.; Laub, A. J.; Chilali, M., LMI control toolbox for use with Matlab (1995), The Math.Works Inc.: The Math.Works Inc. Natick, MA |
| [14] | Gao, H.; Chen, T., Stabilization of nonlinear systems under variable sampling: a fuzzy control approach, IEEE Transactions on Fuzzy Systems, 15, 5, 972-983 (2007) |
| [15] | Goh, B. S.; Leitmann, G.; Vincent, T. L., Optimal control of a prey-predator system, Mathematical Biosciences, 19, 3-4, 263-286 (1974) · Zbl 0297.92013 |
| [16] | Guerra, T. M.; Vermeiren, L., LMI-based relaxed nonquadratic stabilization conditions for nonlinear systems in the Takagi-Sugeno’s form, Automatica, 40, 5, 823-829 (2004) · Zbl 1050.93048 |
| [17] | Keulen, van B., \(H_\infty \)-control for distributed parameter systems: a state-space approach (1993), Birkhauser: Birkhauser Boston, MA · Zbl 0788.93018 |
| [18] | Khalil, H. K., Nonlinear systems (2002), Prentice-Hall: Prentice-Hall Upper Saddle River, NJ · Zbl 0626.34052 |
| [19] | Lee, D. H.; Park, J. B.; Joo, Y. H., Approaches to extended non-quadratic stability and stabilization conditions for discrete-time Takagi-Sugeno fuzzy systems, Automatica, 47, 3, 534-538 (2011) · Zbl 1216.93071 |
| [20] | Levine, I. N., Quantum chemistry (2009), Pearson Prentice Hall: Pearson Prentice Hall New Jersey |
| [21] | Li, H.-X.; Qi, C., Modeling of distributed parameter systems for applications-a synthesized review from time-space separation, Journal of Process Control, 20, 8, 891-901 (2010) |
| [22] | Mozelli, L. A.; Palhares, R. M.; Souza, F. O.; Mendes, E. M.A. M., Reducing conservativeness in recent stability conditions of TS fuzzy systems, Automatica, 45, 6, 1580-1583 (2009) · Zbl 1166.93344 |
| [23] | Pazy, A., Semigroups of linear operators and applications to partial differential equations (1983), Springer-Verlag: Springer-Verlag New York · Zbl 0516.47023 |
| [24] | Ray, W. H., Advanced process control (1981), McGraw-Hill: McGraw-Hill New York |
| [25] | Shang, H.; Frobes, J. F.; Guay, M., Model predictive control for quasilinear hyperbolic distributed parameter systems, Industrial & Engineering and Chemistry Research, 43, 9, 2140-2149 (2004) |
| [26] | Sira-Ramirez, H., Distributed sliding mode control in systems described by quasilinear partial differential equations, Systems & Control Letters, 13, 2, 177-181 (1989) · Zbl 0684.93044 |
| [27] | Takagi, T.; Sugeno, M., Fuzzy identification of systems and its applications to modeling and control, IEEE Transactions on Systems, Man, Cybernetics, 15, 1, 116-132 (1985) · Zbl 0576.93021 |
| [28] | Tanaka, K.; Hori, T.; Wang, H. O., A multiple Lyapunov function approach to stabilization of fuzzy control systems, IEEE Transactions on Fuzzy Systems, 11, 4, 582-589 (2003) |
| [29] | Tanaka, T.; Wang, H. O., Fuzzy control systems design and analysis: a linear matrix inequality approach (2001), Wiley: Wiley New York |
| [30] | Tuan, H. D.; Apkarian, P.; Narikiyo, T.; Yamamoto, Y., Parameterized linear matrix inequality techniques in fuzzy control system design, IEEE Transactions on Fuzzy Systems, 9, 2, 324-332 (2001) |
| [31] | Wang, J.-W.; Wu, H.-N.; Li, H.-X., Distributed fuzzy control design of nonlinear hyperbolic PDE systems with application to nonisothermal plug-flow reactor, IEEE Transactions on Fuzzy Systems, 19, 3, 514-526 (2011) |
| [32] | Wu, H.-N., An ILMI approach to robust \(H_2\) static output feedback fuzzy control for uncertain discrete-time nonlinear systems, Automatica, 44, 9, 2333-2339 (2008) · Zbl 1153.93442 |
| [33] | Wu, H.-N.; Li, H.-X., Finite-dimensional constrained fuzzy control of a class of nonlinear distributed process systems, IEEE Transactions on Systems, Man, Cybernetics-Part B: Cybernetics, 37, 5, 1422-1430 (2007) |
| [34] | Wu, H.-N.; Li, H.-X., \(H_\infty\) fuzzy observer-based control for a class of nonlinear distributed parameter systems with control constraints, IEEE Transactions on Fuzzy Systems, 16, 2, 502-516 (2008) |
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