Document Type : Research Articles
Author
Department of Mathematics, Faculty of Science, University of Zanjan, Zanjan, Iran
Abstract
Objective: In this article, time-varying chaotic systems with uncertainties, including external disturbances, are considered, and sliding mode control (SMC) is used to control such systems. To control these systems, an autonomous differential equation is first introduced. Then, based on this differential equation, a sliding surface is defined to control this chaotic system. This kind of controller is remarkable in that it removes the effects of disturbances, whether bounded or unbounded. Therefore, the system is known to be fixed-time stable. where the trajectories of this chaotic system are not placed on the sliding surface, we have created creative controllers to place the trajectories on the sliding surface in finite time. Theoretical investigations show that such chaotic systems can be made fixed-time stable by applying the controls proposed in this study. Based on the findings of this study, the controllers are designed to eliminate all disturbances, whether bounded or unbounded. the results be said to apply chaotic, time-dependent, and time-independent systems. To further consolidate the results obtained in this article, two examples, namely the time-dependent system of the Gyro and the time-independent system of the Liu, are investigated, and the results were compared with previous works by other researchers.
Keywords
- Chaotic systems
- Sliding mode control
- Time-dependent systems
- Time-independent systems
- Fixed-time stability
Main Subjects
[1] X. Zhang, X. Liu, and Q. Zhu, Adaptive chatter free sliding mode control for a class of uncertain chaotic systems. Applied Mathematics and Computation, 2014. 232: p. 431-435.
[2] E. Zeraoulia, and J.C. Sprott, Robust chaos and its applications. World Scientific series on nonlinear science. Series A, Monographs and treatises, v. 79. 2012, Singapore: World Scientific.
[3] C. Guanrong, Chaos theory and applications: a new trend. 2021, Akif AKGÜL. p. 1-2.
[4] M. Jun, Chaos Theory and Applications:The Physical Evidence, Mechanism are Important in Chaotic Systems. Chaos Theory and Applications, 2022. 4(1).
[5] S. Vaidyanathan, and C. Volos, Advances and Applications in Chaotic Systems. 1st 2016. ed. Studies in Computational Intelligence, 636. 2016, Cham: Springer International Publishing.
[6] A. Ouannas, et al., Synchronization of Fractional Hyperchaotic Rabinovich Systems via Linear and Nonlinear Control with an Application to Secure Communications. International Journal of Control, Automation and Systems, 2019. 17(9): p. 2211-2219.
[7] S. Mobayen, et al., Barrier function-based adaptive nonsingular sliding mode control of disturbed nonlinear systems: A linear matrix inequality approach. Chaos, Solitons & Fractals, 2022. 157: p. 111918.
[8] K. A. Alattas, et al., Nonsingular Integral-Type Dynamic Finite-Time Synchronization for HyperChaotic Systems. Mathematics, 2022. 10(1): p. 115.
[9] C. K. Tse, Controlling chaos and bifurcations in engineering systems, Guanrong Chen, Boca Raton, FL: CRC Press, 2000, ISBN 0-8493-0579-9. International Journal of Robust and Nonlinear Control, 2001. 11(4): p. 393-397.
[10] Z. Liu, and H. Pan, Barrier function-based adaptive sliding mode control for application to vehicle suspensions. IEEE Transactions on Transportation Electrification, 2020. 7(3): p. 2023-2033.
[11] L. Zhang, C. Zhang, and D. Zhao, Control of a class of chaotic systems by a stochastic delay method. Kybernetika, 2010. 46(1): p. 38-49.
[12] P. Y. Xiong, et al., Spectral entropy analysis and synchronization of a multi-stable fractional-order chaotic system using a novel neural network-based chattering-free sliding mode technique. Chaos, Solitons & Fractals, 2021. 144: p. 110576.
[13] R. Wang, et al., Fuzzy neural network-based chaos synchronization for a class of fractional-order chaotic systems: an adaptive sliding mode control approach.Nonlinear Dynamics, 2020. 100: p. 1275-1287.
[14] Z. Ma, et al., Recursive Feasibility and Stability for Stochastic MPC based on Polynomial Chaos. IFACPapersOnLine, 2023. 56(1): p. 204-209.
[15] A. Modiri, and S. Mobayen, Adaptive terminal sliding mode control scheme for synchronization of fractionalorder uncertain chaotic systems. ISA transactions, 2020. 105: p. 33-50.
[16] M. H. Barhaghtalab, S. Mobayen, and F. MerrikhBavat. Design of a global sliding mode controller using hyperbolic functions for nonlinear systems and application in chaotic systems. in 2019 27th Iranian Conference on Electrical Engineering (ICEE). 2019. IEEE.
[17] S. Ha, et al., Backstepping-based adaptive fuzzy synchronization control for a class of fractional-order chaotic systems with input saturation. International Journal of Fuzzy Systems, 2019. 21: p. 1571-1584.
[18] S. Ha, H. Liu, and S. Li, Adaptive fuzzy backstepping control of fractional-order chaotic systems with input saturation. Journal of Intelligent & Fuzzy Systems, 2019. 37(5): p. 6513-6525.
[19] O. Mofid, S. Mobayen, and M.H. Khooban, Sliding mode disturbance observer control based on adaptive synchronization in a class of fractional‐order chaotic systems. International Journal of Adaptive Control and Signal Processing, 2019. 33(3): p. 462-474.
[20] H. Jahanshahi, et al., Entropy analysis and neural network-based adaptive control of a non-equilibrium four-dimensional chaotic system with hidden attractors. Entropy, 2019. 21(2): p. 156.
[21] G. Rigatos, and M. Abbaszadeh, Nonlinear optimal control and synchronization for chaotic electronic circuits. Journal of Computational Electronics, 2021. 20: p. 1050-1063.
[22] C. Letellier, and J. P. Barbot, Optimal flatness placement of sensors and actuators for controlling chaotic systems. Chaos: An Interdisciplinary Journal of Nonlinear Science, 2021. 31(10).
[23] C. Liu, et al., A new chaotic attractor. Chaos, Solitons & Fractals, 2004. 22: p. 1031-1038.
[24] L. Crespo, and J.Q. Sun, On the Feedback Linearization of the Lorenz System. Journal of Vibration and Control - J VIB CONTROL, 2004. 10: p. 85-100.
[25] H. Su, et al., Fixed time stability of a class of chaotic systems with disturbances by using sliding mode control. ISA transactions, 2021. 118: p. 75-82.
[26] H. Li, et al., Chaos control and synchronization via a novel chatter free sliding mode control strategy. Neurocomputing, 2011. 74(17): p. 3212-3222.
[27] J. Hu, et al., A survey on sliding mode control for networked control systems. International Journal of Systems Science, 2021. 52(6): p. 1129-1147.
[28] J. Hu, et al., Design of sliding-mode-based control for nonlinear systems with mixed-delays and packet losses under uncertain missing probability. IEEE Transactions on Systems, Man, and Cybernetics: Systems, 2019. 51(5): p. 3217-3228.
[29] F. Roshanravan, A. Heydari, Sliding Mode Control Design for a Class of Nonlinear Fractional Systems with Application to Glucose-Insulin Systems. International Journal of Industrial Electronics, Control and Optimization, 2002.
[30] M. K. Naik, et al., Design of a fractional-order atmospheric model via a class of ACT-like chaotic system and its sliding mode chaos control. Chaos: An Interdisciplinary Journal of Nonlinear Science, 2023. 33(2).
[31] C. Baishya, et al., Chaos control of fractional order nonlinear Bloch equation by utilizing sliding mode controller. Chaos, Solitons & Fractals, 2023. 174: p. 113773.
[32] H. Su, et al., Robust fixed time control of a class of chaotic systems with bounded uncertainties and disturbances. International Journal of Control, Automation and Systems, 2022. 20(3): p. 813-822.
[33] A. Rezaie, et al., Design of a Fixed-Time Stabilizer for Uncertain Chaotic Systems Subject to External Disturbances. Mathematics, 2023. 11(15): p. 3273.
[34] M. A. Sepestanaki, et al., Chattering-Free Terminal Sliding Mode Control Based on Adaptive Barrier Function for Chaotic Systems With Unknown Uncertainties. IEEE Access, 2022. 10: p. 103469-103484.
[35] Y. Chen, X. Li, and S. Liu, Finite-time stability of ABC type fractional delay difference equations. Chaos, Solitons & Fractals, 2021. 152: p. 111430.
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