Partial differential equation modeling and vibration control for a nonlinear 3D rigid‐flexible manipulator system with actuator faults

Cao, Fangfei; Liu, Jinkun

doi:10.1002/rnc.4587

Cited by 21 publications

(18 citation statements)

References 27 publications

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“…A great deal of researches have been carried out to avoid this problem. [30][31][32][33][34] For a class of dynamic systems with unknown actuator faults, a fault-tolerant controller is designed in Reference 35 to solve the problem. Aiming at the uncertain faults of the rigid-flexible coupling system in Reference 36, a novel fault-tolerant control strategy is put forward on the basis of the sliding mode control method of backstepping.…”

Section: Introductionmentioning

confidence: 99%

Tangent barrier Lyapunov function‐based constrained control of flexible manipulator system with actuator failure

Tang

Liu

2021

Intl J Robust & Nonlinear

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This article puts forward an adaptive neural network fault-tolerant control scheme under the state constraints for the flexible manipulator system with uncertain terms. The dynamic model of the system is described by partial differential equations. The tangent barrier Lyapunov functions are chosen in the design process for the sake of ensuring that all states in the system satisfy the constrained conditions. The uncertainties resulted from load mass, hub inertia, and bending stiffness in the system are approximated by using the universal approximation property of neural networks. The adaptive method is used to counteract the influence of joint motor actuator failure. At the same time, combining with the backstepping design framework to design effective controllers to assure that all signals in the closed-loop system are bounded. Lyapunov stability analysis method is used to prove the stability of the system. Finally, the simulation results prove the availability of the raised control method.

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Section: Introductionmentioning

confidence: 99%

Tangent barrier Lyapunov function‐based constrained control of flexible manipulator system with actuator failure

Tang

Liu

2021

Intl J Robust & Nonlinear

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“…Considering flexible spacecraft, Ji, Liu [29] design an adaptive distributed control scheme to suppress the deformation and ensure the system stable in the presence of actuator fault. Vibration control with actuator faults is addressed to eliminate the deformation of the two-link rigid-flexible manipulator [30]. However, the works mentioned above are about the researches on input constraint and actuator fault tolerance respectively.…”

Section: Introductionmentioning

confidence: 99%

Boundary Control of A Flexible Rotatable Manipulator in Three-Dimensional Space With Input Constraints and Actuator Faults

Wang

Liu

Cao

2021

Preprint

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In this paper, the boundary control problem of a flexible rotatable manipulator in Three-Dimensional space with input constraints and actuator faults is taken into account. The Hamilton principle is introduced to derive the dynamic model represented by partial differential equations (PDEs), which can accurately reflect the characteristics of the distributed parameters of the flexible system. The hyperbolic tangent function is adopted to ensure that the control input is within a bounded range, and the projection-based adaptive laws are designed to estimate the degree of unknown actuator failures. Satisfying the input constraints, the system can still remain stable when the actuator failures ensue. The flexible manipulator can track the required angle, and both the elastic deformation and the deformation rate are effectively suppressed simultaneously. The numerical simulation results further illustrate the effectiveness of the proposed controller.

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“…The flexible structure is usually modeled into distributed parameter systems described by partial differential equation (PDE). However, the flexible part modeled by PDE with infinite dimensions is more difficult for control design comparing with the rigid part 6‐9 …”

Section: Introductionmentioning

confidence: 99%

“…To tackle the aforementioned problem, researchers investigated the PDE control of the flexible manipulator, because their models contain the infinite‐dimensional modes and overcome spillover instability 6 . Recently, boundary control strategy has been widely proposed for addressing flexible structure systems in order to avoid the spillover effects of the truncated model‐based control 6‐8 . In Reference 8, based on the Lyapunov's direct method, boundary control is designed for ensuring the stability of the Timoshenko beam system and copying with the input dead‐zone.…”

Section: Introductionmentioning

confidence: 99%

“…Another boundary output feedback law is proposed to reject general external disturbance for Euler‐Bernoulli beam systems in Reference 9. Although the boundary control has been studied widely for flexible systems, few studies have addressed for a two‐link rigid‐flexible manipulator 4‐6 . To make up the partial loss of actuators effectiveness, an adaptive boundary compensation control for the rigid‐flexible manipulator is studied in Reference 4.…”

Section: Introductionmentioning

confidence: 99%

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Disturbance observer‐based adaptive boundary iterative learning control for a rigid‐flexible manipulator with input backlash and endpoint constraint

Zhou

Wang

Tian

et al. 2020

Adaptive Control & Signal

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Summary In this article, an observer‐based adaptive boundary iterative learning control law is developed for a class of two‐link rigid‐flexible manipulator with input backlash, the unknown external disturbance, and the endpoint constraint. To tackle the backlash nonlinearities and ensure the vibration suppression, the disturbance observers based upon the iterative learning conception are considered in the adaptive boundary control design. A barrier Lyapunov function is incorporated with boundary control law to restrict the endpoint state. Based on the defined barrier composite energy function, the tracking angle error convergence of the rigid part is guaranteed, and the vibrations of the flexible part are suppressed through the rigorous analysis. Finally, a numerical simulation is provided to illustrate the effectiveness of the proposed control.

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Partial differential equation modeling and vibration control for a nonlinear 3D rigid‐flexible manipulator system with actuator faults

Cited by 21 publications

References 27 publications

Tangent barrier Lyapunov function‐based constrained control of flexible manipulator system with actuator failure

Tangent barrier Lyapunov function‐based constrained control of flexible manipulator system with actuator failure

Boundary Control of A Flexible Rotatable Manipulator in Three-Dimensional Space With Input Constraints and Actuator Faults

Disturbance observer‐based adaptive boundary iterative learning control for a rigid‐flexible manipulator with input backlash and endpoint constraint

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