Multi-time-scale 3-D coordinated formation control for multi-underactuated AUV with uncertainties: Design and stability analysis using singular perturbation methods

This paper is concerned with a multi-underactuated AUV three-dimensional (3-D) formation control method with a multi-time-scale structure in the presence of uncertain nonlinearities and environmental disturbances. First, a double-layer independent position-velocity fixed topology is adopted to overc...

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Vydáno v:Ocean engineering Ročník 230; s. 109053
Hlavní autoři: Xia, Guoqing, Zhang, Yu, Zhang, Wei, Chen, Ximing, Yang, Haoyu
Médium: Journal Article
Jazyk:angličtina
Vydáno: Elsevier Ltd 15.06.2021
Témata:
Extended high-gain observer
Integral sliding mode control
Multi time scale
Multi-underactuated AUV system
Singular perturbation
Uncertainties
Multi time scale
Integral sliding mode control
Extended high-gain observer
Multi-underactuated AUV system
Uncertainties
Singular perturbation
ISSN:0029-8018, 1873-5258
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Shrnutí:This paper is concerned with a multi-underactuated AUV three-dimensional (3-D) formation control method with a multi-time-scale structure in the presence of uncertain nonlinearities and environmental disturbances. First, a double-layer independent position-velocity fixed topology is adopted to overcome the drawback of narrow bandwidth of underwater communication. Then, an extended high-gain observer (EHGO) is utilized to provide compensation to uncertain nonlinearities and environmental disturbances. Moreover, the consensus theory is incorporated with an integral sliding mode controller to guarantee that the multi-underactuated AUV system can track the desired trajectory while maintaining the predefined formation. In addition, based on the analysis for the whole formation control system, the extended high-gain observer is on the ultra-fast time scale, the integral sliding mode controller is on the fast time scale, and the system state converges to the desired state on the slow time scale. Such multi-time scale structure allows independent analysis of the dynamics in each time scale, and the singular perturbation method is effectively utilized to establish the exponential stability of the equilibrium. Finally, simulation results are presented to illustrate the control performance. •The underactuated AUV formation system is uniquely analyzed by combining the multi-time-scale decomposition phenomenon and the singular perturbation theory.•The dynamic analysis of the system is carried out independently in each time scale, which significantly reduces the difficulty of designing the controller and analyzing the stability of the system.•The proposed formation controller combines the consensus theory and the integral sliding mode controller, so that the formation system can accurately track the desired path while maintaining the stability of the formation system.•A double-layer independent position-velocity fixed topology is adopted to overcome the drawback of narrow bandwidth of underwater communication.•An extended high-gain observer (EHGO) is designed to solve the problems of the lumped uncertainties in the system.
ISSN:0029-8018
1873-5258
DOI:10.1016/j.oceaneng.2021.109053