Iterative Learning Control for Trajectory Tracking of Robot Manipulators

Q4 Computer Science

International Journal of Automation and Smart Technology Pub Date : 2017-09-01 DOI:10.5875/AUSMT.V7I3.1410

T. Hsiao, P. Huang

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引用次数: 26

Abstract

Iterative learning control (ILC) has been shown to be effective in improving tracking performance of repetitive tasks, and is widely used in the motion control systems of CNC machines, semiconductor manufacturing equipment, hard disk drives, etc. However, applying ILC to robot manipulators requires careful consideration of nonlinear dynamics. We propose using a computed torque controller and the disturbance observer (DOB) to robustly linearize the dynamics of robot manipulators. The PD feedback controller is then applied for each joint to achieve the desired bandwidth and damping ratio. Both control-based ILC and command-based ILC are implemented separately in the linearized system as a feedforward compensator to enhance trajectory tracking accuracy. The proposed control system is realized in a six-axis industrial robot. Experimental results show that DOB is indispensable for robust feedback linearization so that ILC can work on the linearized system to improve the tracking performance for repetitive motion. Satisfactory and similar performance is accomplished by both control-based ILC and command-based ILC.

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机械臂轨迹跟踪的迭代学习控制

迭代学习控制(ILC)在提高重复任务的跟踪性能方面已被证明是有效的，并广泛应用于数控机床、半导体制造设备、硬盘驱动器等运动控制系统中。然而，将ILC应用于机器人操纵臂需要仔细考虑非线性动力学。我们提出使用计算扭矩控制器和扰动观测器(DOB)来鲁棒线性化机器人操纵臂的动力学。然后对每个关节应用PD反馈控制器以获得所需的带宽和阻尼比。基于控制的ILC和基于命令的ILC分别作为前馈补偿器在线性化系统中实现，以提高轨迹跟踪精度。该控制系统在六轴工业机器人上实现。实验结果表明，对于鲁棒反馈线性化，DOB是必不可少的，这样ILC才能在线性化后的系统上工作，从而提高重复运动的跟踪性能。基于控制的ILC和基于命令的ILC都实现了令人满意和相似的性能。

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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来源期刊

International Journal of Automation and Smart Technology Engineering-Electrical and Electronic Engineering

CiteScore

0.70

自引率

0.00%

发文量

审稿时长

16 weeks

期刊介绍： International Journal of Automation and Smart Technology (AUSMT) is a peer-reviewed, open-access journal devoted to publishing research papers in the fields of automation and smart technology. Currently, the journal is abstracted in Scopus, INSPEC and DOAJ (Directory of Open Access Journals). The research areas of the journal include but are not limited to the fields of mechatronics, automation, ambient Intelligence, sensor networks, human-computer interfaces, and robotics. These technologies should be developed with the major purpose to increase the quality of life as well as to work towards environmental, economic and social sustainability for future generations. AUSMT endeavors to provide a worldwide forum for the dynamic exchange of ideas and findings from research of different disciplines from around the world. Also, AUSMT actively seeks to encourage interaction and cooperation between academia and industry along the fields of automation and smart technology. For the aforementioned purposes, AUSMT maps out 5 areas of interests. Each of them represents a pillar for better future life: - Intelligent Automation Technology. - Ambient Intelligence, Context Awareness, and Sensor Networks. - Human-Computer Interface. - Optomechatronic Modules and Systems. - Robotics, Intelligent Devices and Systems.