Chattering-Free Terminal Sliding Mode Control Based on Adaptive Barrier Function for Chaotic Systems With Unknown Uncertainties

Sepestanaki, Mohammadreza Askari; Barhaghtalab, Mojtaba Hadi; Mobayen, Saleh; Jalilvand, Abolfazl; Fekih, Afef; Skruch, Paweł

doi:10.1109/access.2022.3209993

Cited by 13 publications

(8 citation statements)

References 52 publications

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“…To break through this limitation, the finite-time control theory has attracted wide attention due to its fast response performance, strong robustness, and high control accuracy. [30][31][32][33][34][35][36] Detailedly, a finite-time distributed adaptive consensus control problem was studied in Reference 36 for nonlinear MASs by using a funnel technique. Currently, the existing research results on finite-time problems of MASs have predominantly focused on consensus control, neglecting other important aspects.…”

Section: Introductionmentioning

confidence: 99%

“…The various control methods mentioned above can only guarantee that the variables in the system reach equilibrium points in infinite time. To break through this limitation, the finite‐time control theory has attracted wide attention due to its fast response performance, strong robustness, and high control accuracy 30–36 . Detailedly, a finite‐time distributed adaptive consensus control problem was studied in Reference 36 for nonlinear MASs by using a funnel technique.…”

Section: Introductionmentioning

confidence: 99%

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Adaptive finite‐time optimal time‐varying formation control for second‐order stochastic nonlinear multiagent systems

Zhang,

Fu,

2024

Adaptive Control & Signal

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SummaryThis work addresses a fuzzy‐based finite‐time optimal time‐varying formation (TVF) control issue for a class of second‐order stochastic multi‐agent systems (SMASs) with unknown nonlinearities. First, novel optimal cost functions with exponential power terms are constructed, which enables the SMASs to achieve finite‐time stability in the mean square sense with minimum cost. Then, based on the cost functions, an optimal controller is proposed, in which fuzzy logic systems (FLSs) are used as universal approximators to identify the unknown uncertainties. Theorem analyses show that the proposed control strategy can guarantee the mean‐square finite‐time bounded of all signals in the system and then the TVF control task can be simultaneously realized with minimum cost. Finally, the effectiveness of the presented control method is verified by a multiple omni‐directional robot system.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Adaptive finite‐time optimal time‐varying formation control for second‐order stochastic nonlinear multiagent systems

Zhang,

Fu,

2024

Adaptive Control & Signal

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“…In addition, by the combination of this adaptive technique‐based barrier function with a first‐order SMC, a class of first‐order disturbed systems is controlled [57]. A chattering‐free TSMC technique based on the adaptive barrier function for controlling chaotic systems in the presence of unknown uncertainties has been introduced in Sepestanaki et al [58], which is based on the Lyapunov stability theory and the adaptive control method; this method has demonstrated favorable outcomes in controlling chaos in this class of chaotic systems. By implementing the proposed method in the mentioned research, the convergence of the state variables in the chaotic system is guaranteed independent of the uncertainty ranges and keeps them in the around of the origin without high estimated the control gain.…”

Section: Introductionmentioning

confidence: 99%

Adaptive barrier function‐based fractional‐order chattering‐free finite‐time control for uncertain chaotic systems

Sepestanaki

Soofi

Barhaghtalab

et al. 2023

Math Methods in App Sciences

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This study proposes the adaptive continuous barrier function as the fractional‐order control system using the terminal sliding mode control technique with chattering‐free property to stabilize chaotic systems that have unknown uncertainties. The important reason for using the fractional‐order controller is its greater flexibility than the integer‐order controller. Using adaptive approach and Lyapunov's stability theory, an adaptive continuous barrier fractional‐order chattering‐free finite‐time controller for a category of chaotic systems with the unknown uncertainties and external disturbances is presented. The suggested controller can stabilize the chaotic system excellently with a continuous and smooth control law even without knowing the boundaries and in the presence of unknown disturbances due to the model uncertainties. According to MATLAB simulation results, the high efficiency of the suggested control technique to control the chaotic systems in the attendance of unknown perturbations is obviously confirmed.

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“…T HE disturbance rejection property of sliding mode control of second order systems has already been widely emphasized in many publications and applications. Many of these previous works assume an affine relation between the control variable and the system acceleration [1]- [6].…”

Section: Introductionmentioning

confidence: 99%

Variable Structure Control of Second Order Systems With Nonlinear Uncertain Discontinuous Input Functions Using Approximate Inverses

2022

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We consider second order nonlinear systems in control canonical form, where the functional relation between the control variable and the system acceleration is nonlinear, uncertain and discontinuous. We approximate the nonlinear uncertain and discontinuous function with an invertible one, and use variable structure control theory to suppress the error of the approximate inverse. We rewrite the finite time reaching law or the terminal reaching law into the form of inequalities and use these inequalities to design a control law that drives the system state to the sliding surface in finite time, and one that ensures the convergence of the system speed and position errors to a narrow, adjustable width band around zero. The stability of the control system is also analyzed and proven. We demonstrate how to ensure the sufficiency of the available control effort, by the proper design of control parameters. The method is then validated on a numerical model of a nonlinear system with nonlinear, uncertain and discontinuous input function.

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Chattering-Free Terminal Sliding Mode Control Based on Adaptive Barrier Function for Chaotic Systems With Unknown Uncertainties

Cited by 13 publications

References 52 publications

Adaptive finite‐time optimal time‐varying formation control for second‐order stochastic nonlinear multiagent systems

Adaptive finite‐time optimal time‐varying formation control for second‐order stochastic nonlinear multiagent systems

Adaptive barrier function‐based fractional‐order chattering‐free finite‐time control for uncertain chaotic systems

Variable Structure Control of Second Order Systems With Nonlinear Uncertain Discontinuous Input Functions Using Approximate Inverses

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