Robust Nonsingular Terminal Sliding Mode Control of Radius for a Bubble Between Two Elastic Walls

Badfar, Ehsan; Ardestani, Mahdi Alinaghizadeh; Beheshti, Mohammad Taghi Hamidi

doi:10.1007/s40313-019-00558-8

Cited by 4 publications

(2 citation statements)

References 31 publications

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“…Many studies in the literature have made efforts to alleviate or eliminate this problem. In (Badfar et al 2020), the chattering phenomenon in the con- trol input signal of the proposed finite-time SMC method has been eliminated by replacing the hyperbolic tangent function instead of the signum function. However, the stability analysis of the closed-loop system using a hyperbolic tangent function in control law has not been established in this study.…”

Section: Introductionmentioning

confidence: 99%

Chattering-Free Trajectory Tracking Robust Predefined-Time Sliding Mode Control for a Remotely Operated Vehicle

Hosseinabadi

Abadi

Mekhilef

et al. 2020

J Control Autom Electr Syst

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This study investigates a new chattering-free robust predefined-time sliding mode control (CFRPSMC) scheme for the trajectory tracking control problem of a three-degree-of-freedom (3-DOF) remotely operated vehicle (ROV) in the presence of matched uncertainties. The advanced notion of predefined-time stability is used to provide a maximum convergence time as desired that can be set during the control design and independently of the initial conditions. Based on defining a new form of sliding surfaces, a new control law is designed to ease the undesirable chattering phenomenon without damaging the robustness properties and tracking precision. The proposed control scheme can not only solve the predefined-time tracking controller design problem, but also provide the robustness to various uncertainties. The Lyapunov stability theory is used to establish the stability analysis of the closed-loop system in both the reaching phase and the sliding phase. The performance of the proposed CFRPSMC scheme is evaluated for the 3-DOF ROV through two comparative simulation cases using Simulink/MATLAB. The comparative simulation results and analytical comparisons demonstrate the efficacy and superiority of the proposed method compared with other relevant conventional methods.

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Section: Introductionmentioning

confidence: 99%

Chattering-Free Trajectory Tracking Robust Predefined-Time Sliding Mode Control for a Remotely Operated Vehicle

Hosseinabadi

Abadi

Mekhilef

et al. 2020

J Control Autom Electr Syst

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show abstract

“…Because of the simple structure and robust behavior against parametric uncertainty and external disturbances, the sliding mode control (SMC) has become a popular method. SMC has been applied successfully to a variety of systems such as medical systems (Badfar & Ardestani, 2019;Badfar, Ardestani, & Beheshti, 2020), mechanical systems (Amirkhani, Mobayen, Iliaee, Boubaker, & Hosseinnia, 2019;Bessa, Otto, Kreuzer, & Seifried, 2019;Peza-Solis, Silva-Navarro, & Castro-Linares, 2015) and electrical converters (Asgari, 2019;Li, Liu, & Su, 2019). Recently, the terminal sliding mode control (TSMC) has been introduced to guarantee the finite-time convergence and higher precision of tracking error (Du, Chen, Wen, Yu, & Lü, 2018).…”

Section: Introductionmentioning

confidence: 99%

Design of an adaptive nonsingular terminal sliding mode using supervisory fuzzy for the output voltage control of a buck converter

Badfar¹,

Abdollahi²

2020

JART

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The buck converter is widely utilized in various applications such as solar chargers, electrical vehicles and space exploration. The use of an efficient controller in buck converters reduces the heat and losses, extends the useful life, and allows for smaller gadgets to be built. In this research, a novel technique is proposed to regulate the output voltage of the buck converter. For this purpose, the mathematical model of the converter is introduced. Next, the adaptive sliding mode is suggested to regulate the output voltage. In order to ensure the faster transient response and finite-time convergence, the terminal sliding mode control is suggested. The singularity problem is solved by using nonsingular terminal sliding mode control. The switching gain is adaptively scheduled according to the fuzzy logic system. Finally, some simulation results including the parametric uncertainties, measurement noise, and steady-state error analysis are illustrated to demonstrate the efficiency of the proposed controller.

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Design of adaptive fuzzy gain scheduling fast terminal sliding mode to control the radius of bubble in the blood vessel with application in cardiology

Badfar

Ardestani

2020

Int. J. Dynam. Control

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Robust Nonsingular Terminal Sliding Mode Control of Radius for a Bubble Between Two Elastic Walls

Cited by 4 publications

References 31 publications

Chattering-Free Trajectory Tracking Robust Predefined-Time Sliding Mode Control for a Remotely Operated Vehicle

Chattering-Free Trajectory Tracking Robust Predefined-Time Sliding Mode Control for a Remotely Operated Vehicle

Design of an adaptive nonsingular terminal sliding mode using supervisory fuzzy for the output voltage control of a buck converter

Design of adaptive fuzzy gain scheduling fast terminal sliding mode to control the radius of bubble in the blood vessel with application in cardiology

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