Adaptive prescribed time control for quadrotor formation with stochastic links failure

Shang, Wei; Jing, Guohao; Wang, Yulin; Chen, Tianlong; Liu, Zhou; Zheng, Zhongzhong

doi:10.1002/asjc.2967

Asian Journal of Control

2022

DOI: 10.1002/asjc.2967

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Adaptive prescribed time control for quadrotor formation with stochastic links failure

Wei Shang

Guohao Jing

Yulin Wang

et al.

Abstract: The formation control for multiple quadrotors subject to maintaining the formation configuration and collision avoidance in the situation of stochastic links failure is investigated in this paper. First, the distributed formation controller is designed, the position controller is developed to manage the desired formation of position, and the attitude controller is developed to control the translation and rotation movements of the quadrotor. Then, in order to avoid the collisions between multiple quadrotors and… Show more

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Cited by 3 publications

References 38 publications

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Adaptive prescribed‐time control for nonlinear systems with uncertain time‐varying parameters and control gains

Ji,

Niu,

Gao

et al. 2024

Asian Journal of Control

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This article investigates the adaptive prescribed‐time dynamic surface control (PTDSC) problem for a class of nonlinear strict‐feedback systems with uncertain time‐varying parameters and unknown control gains. First, the spatiotemporal transformation method is employed to eliminate the effect of the unknown control gains in the nonlinear systems. Then, to deal with the problem of “complexity explosion” in the backstepping design framework, a novel dynamic surface control (DSC) strategy is proposed by adding a time‐varying gain to the nonlinear filter. Furthermore, under the Lyapunov stability theory, the rational adaptive laws are cleverly designed to eliminate the influence of the unknown time‐varying parameters. The PTDSC strategy proposed in this paper can guarantee that all the states of the nonlinear systems and the estimate errors of the nonlinear filters converge to zero within the prescribed time. Lastly, a simulation example is provided to demonstrate the effectiveness of the proposed control algorithm.

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Adaptive prescribed‐time control for nonlinear systems with uncertain time‐varying parameters and control gains

Ji,

Niu,

Gao

et al. 2024

Asian Journal of Control

View full text Add to dashboard Cite

show abstract

Output Feedback Consensus Control of Nonlinear Multi-agent System Under Communication Faults and Actuator Faults

Zheng,

Zhou

2024

Int. J. Control Autom. Syst.

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Adaptive Terminal Sliding Mode Fault-Tolerant Control of Spacecraft Based on the Left Attitude Error Function of SO(3)

Zheng

Shang

Liu

et al. 2023

International Journal of Aerospace Engineering

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For the problem of spacecraft attitude actuator failure, an adaptive terminal sliding mode fault-tolerant controller (ATSMFTC) based on the differential manifold SO(3) modelling is designed in this paper. First, SO(3) is used to provide a global and unique description of the spacecraft attitude dynamic model. This modelling method not only avoids the problems of singularity and unwinding that exist in traditional modelling methods but also the SO(3) modelling has a simple formulation of the dynamic equations. Then a left attitude error descriptor function is constructed on SO(3) to design an ATSMFTC. This controller is capable of fast and accurate tracking of the time-varying desired attitude. At the same time, it can react quickly to maintain system stability in case of spacecraft attitude actuator failure. The controller designed based on the left attitude error description system of SO(3) has the features of small computational effort and simple design process. Finally, the numerical simulation of the attitude tracking error verifies the feasibility and high efficiency of the controller designed in this paper.

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Adaptive prescribed time control for quadrotor formation with stochastic links failure

Cited by 3 publications

References 38 publications

Adaptive prescribed‐time control for nonlinear systems with uncertain time‐varying parameters and control gains

Adaptive prescribed‐time control for nonlinear systems with uncertain time‐varying parameters and control gains

Output Feedback Consensus Control of Nonlinear Multi-agent System Under Communication Faults and Actuator Faults

Adaptive Terminal Sliding Mode Fault-Tolerant Control of Spacecraft Based on the Left Attitude Error Function of SO(3)

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