Vibration control of flexible system with communication delay using wave compensator

2012 12th IEEE International Workshop on Advanced Motion Control (AMC) Pub Date : 2012-03-25 DOI:10.1109/AMC.2012.6197091

E. Saito, S. Katsura

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引用次数: 2

Abstract

Recently, teleoperated robots have been researched for working in ultimate environment actively. Developing performance of teleoperated robots, it will be possible for human to work in such a ultimate environment with safety. However, in the actual case, as gears are used for amplifying output, stiffness of connection part reduces and vibration occurs. Moreover, communication delay causes vibration, too. In addition, in the worst case, the system becomes unstable. Therefore, in this paper, for suppression of the vibration, vibration control using wave compensator is proposed. In the proposal, there are two important control structures. Firstly, reflected wave in the resonant system is eliminated by reflected wave rejection. Transfer function of wave equation without reflected wave is composed of a time delay. Therefore, resonant system can be regarded as time delay system. Next, vibrations from flexible mechanism and communication delay are simultaneously suppressed by wave compensator. Finally, the validity of the proposal is verified by experimental results.

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基于波补偿器的通信延迟柔性系统振动控制

在极限环境下工作的遥控机器人是近年来研究的热点。开发远程操作机器人的性能，将使人类在这样的终极环境中安全工作成为可能。然而，在实际情况中，由于使用齿轮来放大输出，连接部件的刚度降低，产生振动。此外，通信延迟也会引起振动。此外，在最坏的情况下，系统会变得不稳定。因此，为了抑制振动，本文提出了利用波动补偿器进行振动控制。在该方案中，有两个重要的控制结构。首先，通过反射波抑制来消除谐振系统中的反射波。无反射波的波动方程传递函数由时滞组成。因此，谐振系统可以看作是时滞系统。其次，用波补偿器同时抑制柔性机构的振动和通信延迟。最后，通过实验验证了该方案的有效性。

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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2012 12th IEEE International Workshop on Advanced Motion Control (AMC)

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