Interaction Motion Control on Tri-finger Pneumatic Grasper using Variable Convergence Rate Prescribed Performance Impedance Control with Pressure-based Force Estimator

Journal of Robotics and Control (JRC) Pub Date : 2022-09-01 DOI:10.18196/jrc.v3i5.16316

A. Irawan, M. Azahar, Dwi Pebrianti

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引用次数: 2

Abstract

Pneumatic robot is a fluid dynamic based robot system which possesses immense uncertainties and nonlinearities over its electrical driven counterpart. Requirement for dynamic motion handling further challenged the implemented control system on both aspects of interaction and compliance control. This study especially set to counter the unstable and inadaptable proportional motions of pneumatic robot grasper towards its environment through the employment of Variable Convergence Rate Prescribed Performance Impedance Control (VPPIC) with pressure-based force estimation (PFE). Impedance control was derived for a single finger of Tri-finger Pneumatic Grasper (TPG) robot, with improvement being subsequently made to the controller’s output by appropriation of formulated finite-time prescribed performance control. Produced responses from exerted pressure of the maneuvered pneumatic piston were then recorded via derived PEE with adherence to both dynamics and geometry of the designated finger. Validation of the proposed method was proceeded on both circumstances of human hand as a blockage and ping-pong ball as methodical representation of a fragile object. Developed findings confirmed relatively uniform force sensing ability for both proposed PEE and load sensor as equipped to the robot’s fingertip with respect to the experimented thrusting and holding of a human hand. Sensing capacity of the estimator has also advanced beyond the fingertip to enclose its finger in entirety. Whereas stable interaction control at negligible oscillation has been exhibited from VPPIC against the standard impedance control towards gentle and compression-free handling of fragile objects. Overall positional tracking of the finger, thus, justified VPPIC as a robust mechanism for smooth operation amid and succeed direct object interaction, notwithstanding its transcendence beyond boundaries of the prescribed performance constraint.

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基于压力力估计的变收敛速率规定性能阻抗控制的三指气动抓手交互运动控制

气动机器人是一种基于流体动力学的机器人系统，与电动机器人相比，气动机器人具有巨大的不确定性和非线性。动态运动处理的要求进一步对控制系统的交互性和顺应性控制提出了挑战。针对气动机器人抓取器对环境的比例运动不稳定和不适应问题，采用基于压力的力估计的变收敛率规定性能阻抗控制(VPPIC)。推导了三指气动抓握器(TPG)机器人单指的阻抗控制，并利用制定的有限时间规定性能控制对控制器输出进行了改进。由机动气动活塞施加的压力产生的响应，然后通过导出的PEE记录，符合指定手指的动力学和几何形状。在人手作为障碍物和乒乓球作为易碎物体的系统表示的两种情况下，对所提出的方法进行了验证。开发的研究结果证实，相对于实验中人类的手的推力和握持，所提出的PEE和负载传感器装备在机器人的指尖上的力感应能力相对均匀。估计器的感知能力也已经超越了指尖，可以将整个手指包裹起来。然而，VPPIC在可忽略振荡下的稳定相互作用控制已经显示出对标准阻抗控制的温和和无压缩易碎物体的处理。因此，手指的整体位置跟踪证明了VPPIC是一种强大的机制，可以在直接对象交互中顺利操作并成功，尽管它超越了规定性能约束的界限。

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

Journal of Robotics and Control (JRC)

CiteScore

6.30

自引率

0.00%

发文量