Journal ArticleDOI
Adaptive non-singular integral terminal sliding mode tracking control for autonomous underwater vehicles
Lei Qiao,Weidong Zhang +1 more
TLDR
The designed ANITSMC of AUVs avoids the requirement of the prior knowledge of the lumped system uncertainty bounds, provides higher tracking accuracy than the existing globally finite-time stable tracking control (GFTSTC), and offers faster convergence rate and better robustness against dynamic uncertainties and time-varying external disturbances than the adaptive proportional-integral sliding mode control.Abstract:
This study proposes an adaptive non-singular integral terminal sliding mode control (ANITSMC) scheme for trajectory tracking of autonomous underwater vehicles (AUVs) with dynamic uncertainties and time-varying external disturbances. The ANITSMC is first proposed for a first-order uncertain non-linear dynamic system to eliminate the singularity problem in conventional terminal sliding mode control (TSMC) and avoid the requirement of the bound information of the lumped system uncertainty. The time taken to reach the equilibrium point from any initial error is guaranteed to be finite. The proposed ANITSMC is then applied to trajectory tracking control of AUVs. It guarantees that the velocity tracking errors locally converge to zero in finite time and after that the position tracking errors locally converge to zero exponentially. The designed ANITSMC of AUVs avoids the requirement of the prior knowledge of the lumped system uncertainty bounds as opposite to the existing globally finite-time stable tracking control (GFTSTC), provides higher tracking accuracy than the existing GFTSTC and adaptive non-singular TSMC (ANTSMC) and offers faster convergence rate and better robustness against dynamic uncertainties and time-varying external disturbances than the adaptive proportional-integral sliding mode control (APISMC). Comparative simulation results are presented to validate the superiority of the ANITSMC over the APISMC.read more
Citations
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Journal ArticleDOI
Intelligent Bus Platoon Lateral and Longitudinal Control Method Based on Finite-Time Sliding Mode
TL;DR: Considering the rapid convergence of the longitudinal and lateral tracking errors of the platoon, a finite-time tracking control method was proposed in this article , where an adaptive power integral reaching law (APIRL) was proposed for the finite time accessibility of the system approaching mode.
Adaptive Finite-Time Sliding Mode Backstepping Controller for Double-Integrator Systems with Mismatched Uncertainties and External Disturbances
Pooyan Alinaghi Hosseinabadi,Ali Soltani Sharif Abadi,Hemanshu R. Pota,Sundarapandian Vaidyanathana,Saad Mekhilef +4 more
TL;DR: In this article , the authors proposed a method to solve the problem of the problem: the one-dimensional graph of a single node in the graph of the entire graph, i.e.
Journal ArticleDOI
Model-free adaptive control based on prescribed performance and time delay estimation for robotic manipulators subject to backlash hysteresis
TL;DR: In this paper , an adaptive continuous nonsingular fast terminal sliding mode controller combining time delay estimation (TDE) and prescribed performance control (PPC) is formulated to solve the problem of over-dependence on dynamics model and low tracking accuracy of robotic manipulators under uncertainties and backlash hysteresis.
Journal ArticleDOI
Finite-Time Integral Backstepping Nonsingular Terminal Sliding Mode Control to Synchronize a New Six-Term Chaotic System and Its Circuit Implementation
TL;DR: In this article , a finite-time synchronization of a new six-term chaotic system with only stable equilibria and its circuitry implementation is presented, which is designed in such a way that its complex dynamical behavior, including hidden attractors, can be adjusted through only one parameter, whilst allowing transformation to chaotic flows via invariant transformations.
Proceedings ArticleDOI
Cascaded Design for Finite-Time Trajectory Tracking Control of an Underactuated Surface Vehicle
Ziyin Chen,Shuzhi Sam Ge +1 more
TL;DR: In this article , a cascaded design for finitetime trajectory tracking control of an underactuated unmanned surface vehicle (USV) is discussed, where the tracking error dynamics is established with the guidance of a virtual reference vehicle, and transformed into a new cascaded structure, so the control of the overall system can be equivalent to stabilization of two interconnected subsystems separately, which can facilitate the control design by verifying the properties of the interconnection instead of iterative constructing Lyapunov functions for the whole system.
References
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Book
Applied Nonlinear Control
TL;DR: Covers in a progressive fashion a number of analysis tools and design techniques directly applicable to nonlinear control problems in high performance systems (in aerospace, robotics and automotive areas).
Journal ArticleDOI
Continuous finite-time control for robotic manipulators with terminal sliding modes
TL;DR: A continuous finite-time control scheme for rigid robotic manipulators is proposed using a new form of terminal sliding modes using the Lyapunov stability theory, and theoretical analysis and simulation results show that faster and high-precision tracking performance is obtained.
Journal ArticleDOI
Brief Non-singular terminal sliding mode control of rigid manipulators
Yong Feng,Xinghuo Yu,Zhihong Man +2 more
TL;DR: This paper presents a global non-singular terminal sliding mode controller for rigid manipulators to enable the elimination of the singularity problem associated with conventional terminal slide mode control.
Journal ArticleDOI
Continuous finite-time stabilization of the translational and rotational double integrators
TL;DR: A class of bounded continuous time-invariant finite-time stabilizing feedback laws is given for the double integrator because Lyapunov theory is used to prove finite- time convergence.
Journal ArticleDOI
A robust MIMO terminal sliding mode control scheme for rigid robotic manipulators
TL;DR: A robust MIMO terminal sliding mode technique and a few structural properties of rigid robotic manipulators are developed so that the output tracking error can converge to zero in a finite time, and strong robustness with respect to large uncertain dynamics can be guaranteed.