OPTIMAL TRACKING CONTROL FOR ROBOT MANIPULATORS WITH ASYMMETRIC SATURATION TORQUES BASED ON REINFORCEMENT LEARNING

N. D. Dien, Luy Tan Nguyen, L. Lãi
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Abstract

This paper introduces an optimal tracking controller for robot manipulators with asymmetrically saturated torques and partially - unknown dynamics based on a reinforcement learning method using a neural network. Firstly, the feedforward control inputs are designed based on the backstepping technique to convert the tracking control problem into the optimal tracking control problem. Secondly, a cost function of the system with asymmetrically saturated input is defined, and the constrained Hamilton-Jacobi-Bellman equation is built, which is solved by the online reinforcement learning algorithm using only a single neural network. Then, the asymmetric saturation optimal control rule is determined. Additionally, the concurrent learning technique is used to relax the demand for the persistence of excitation conditions. The built algorithm ensures that the closed-loop system is asymptotically stable, the approximation error is uniformly ultimately bounded (UUB), and the cost function converges to the near-optimal value. Finally, the effectiveness of the proposed algorithm is shown through comparative simulations.
基于强化学习的非对称饱和转矩机器人最优跟踪控制
本文介绍了一种基于神经网络强化学习方法的非对称饱和转矩和部分未知动力学的机器人机械臂最优跟踪控制器。首先,基于反演技术设计前馈控制输入,将跟踪控制问题转化为最优跟踪控制问题;其次,定义了输入不对称饱和时系统的代价函数,建立了约束Hamilton-Jacobi-Bellman方程,采用单神经网络在线强化学习算法求解该方程;然后,确定了不对称饱和最优控制规则。此外,采用并行学习技术来放宽对激励条件持续性的要求。该算法保证了闭环系统的渐近稳定,逼近误差一致最终有界,代价函数收敛到近最优值。最后,通过对比仿真验证了所提算法的有效性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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