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考虑漂移角和船岸相互作用的欠驱动船舶自适应神经反步滑模航向控制

Adaptive Neural Backstepping Sliding Mode Heading Control for Underactuated Ships with Drift Angle and Ship-Bank Interaction.

作者信息

Han Xue

机构信息

School of Navigation, Jimei University, Xiamen 361021, Fujian, China.

National-Local Joint Engineering Research Center for Marine Navigation Aids Services, Jimei University, Xiamen 361021, Fujian, China.

出版信息

Comput Intell Neurosci. 2020 Sep 27;2020:8854055. doi: 10.1155/2020/8854055. eCollection 2020.

DOI:10.1155/2020/8854055
PMID:33082777
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7566218/
Abstract

In order to track the desired path under unknown parameters and environmental disturbances, an adaptive backstepping sliding mode control algorithm with a neural estimator is proposed for underactuated ships considering both ship-bank interaction effect and shift angle. Using the features of radial basis function neural network, which can approximate arbitrary function, the unknown parameters of the ship model and environmental disturbances are estimated. The trajectory tracking errors include stabilizing sway and surge velocities errors. Based on the Lyapunov stability theory, the tracking error will converge to zero and the system is asymptotically stable. The controlled trajectory is contractive and asymptotically tends to the desired position and attitude. The results show that compared with the basic sliding mode control algorithm, the overshoot of the adaptive backstepping sliding mode control with neural estimator is smaller and the regulation time of the system is shorter. The ship can adjust itself and quickly reach its desired position under disturbances. This shows that the designed RBF neural network observer can track both the mild level 3 sea state and the bad level 5 sea state, although the wave disturbance has relatively fast time-varying disturbance. The algorithm has good tracking performance and can realize the accurate estimation of wave disturbance, especially in bad sea conditions.

摘要

为了在未知参数和环境干扰下跟踪期望路径,针对欠驱动船舶,考虑船舶与岸壁相互作用效应和偏航角,提出了一种带有神经估计器的自适应反步滑模控制算法。利用径向基函数神经网络能够逼近任意函数的特性,对船舶模型的未知参数和环境干扰进行估计。轨迹跟踪误差包括稳定横荡和纵荡速度误差。基于李雅普诺夫稳定性理论,跟踪误差将收敛到零,系统渐近稳定。所控制的轨迹是收缩的,并渐近趋向于期望的位置和姿态。结果表明,与基本滑模控制算法相比,带有神经估计器的自适应反步滑模控制的超调量更小,系统调节时间更短。船舶能够在干扰下自我调整并快速到达期望位置。这表明所设计的径向基函数神经网络观测器能够跟踪轻度3级海况和恶劣5级海况,尽管波浪干扰具有相对快速的时变扰动。该算法具有良好的跟踪性能,能够实现对波浪干扰的精确估计,特别是在恶劣海况下。

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