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基于神经动态优化的路径引导水面航行器输出反馈有限时间安全关键协调控制

Output-Feedback Finite-Time Safety-Critical Coordinated Control of Path-Guided Marine Surface Vehicles Based on Neurodynamic Optimization

IEEE Transactions on Systems, Man, and Cybernetics: Systems · 2022
被引 36
ABS 3

中文导读

研究了多艘欠驱动海洋水面航行器在速度与输入约束下,面对静态和移动障碍物时的输出反馈有限时间安全关键协调控制方法,通过有限时间状态观测器和控制障碍函数实现分布式编队与避碰。

Abstract

In the presence of static and moving obstacles, this article investigates an output-feedback finite-time safety-critical coordinated control method of multiple under-actuated marine surface vehicles (MSVs) subject to velocity and input constraints. Specifically, based on robust exact differentiators, a finite-time state observer (FTSO) is first developed to recover the unavailable velocities while estimating the total disturbances containing model uncertainties and environmental disturbances. Next, with the aid of estimated velocities from FTSO, a nominal finite-time guidance law is designed for achieving the distributed formation of MSVs at the kinematic level. By the forward invariance principle, finite-time control barrier functions (FTCBFs) are used to construct the collision-free velocity sets for the multi-MSV system. To unify the control and safety objectives, quadratic optimization problems are formulated under collision-free velocity sets and velocity constraints. To facilitate real-time implementations, one-layer recurrent neural networks are employed to solve the quadratic optimization problem. Then, a nominal finite-time control law based on FTSO is presented at the kinetic level. The optimal control laws are solved within the input constraints. All error signals of the closed-loop system are proved to be uniformly ultimately bounded, and the distributed formation of multiple MSVs is ensured to be safe. Simulation results are provided to demonstrate the effectiveness and superiority of the proposed FTCBF-based method.

控制理论海洋工程多智能体系统安全关键控制有限时间控制