不确定初始条件下机械系统具有保证性能的自适应神经控制:一种时变神经元方法

Adaptive Neural Control With Guaranteed Performance for Mechanical Systems Under Uncertain Initial Conditions: A Time-Varying Neuron Approach

IEEE Transactions on Systems, Man, and Cybernetics: Systems · 2024
被引 6
ABS 3

中文导读

提出一种时变神经元自适应控制方案,解决机械系统在动态不确定和初始条件未知下的跟踪性能保证问题,通过变结构网络和移位函数实现低计算负担和预定性能。

Abstract

This article proposes a new adaptive neural control scheme with guaranteed performance for mechanical systems under dynamic uncertainties and uncertain initial conditions. Employing the novel time-varying neuron (TVN) approach and a shifting function, the control method developed in this article can systematically solve two crucial problems: one is how to construct a variable structure network to improve the approximation ability while the online tuning parameters do not increase with the number of neurons, and the other is how to achieve the predetermined tracking performance for multi-input multi-output (MIMO) mechanical systems under any bounded initial tracking errors. To approximate uncertain dynamics, the TVN approach is first presented to instruct the process of adding new neurons for better-learning capability, where the online updating parameters in the neural network (NN) unit are compressed by the vector projection technique, yielding an NN approximator with low-computational burden. By virtue of a shifting function, the uncertain initial tracking error is converted to zero such that a speed function with predetermined convergence performance can be efficiently employed to constrain the tracking trajectory without considering the initial condition. Moreover, to obviate the differentiation operation for the virtual stabilizing function, the dynamic surface technique is adopted to derive the presented control scheme for facilitating practical implementation. Finally, the effectiveness and benefits of the presented control are verified via theoretical analysis and a two-link manipulator.

自适应控制神经网络机械系统跟踪控制