Evaluation of an electromagnetic system with haptic feedback for control of untethered, soft grippers affected by disturbances

2016 6th IEEE International Conference on Biomedical Robotics and Biomechatronics (BioRob) Pub Date : 2016-06-26 DOI:10.1109/BIOROB.2016.7523742

F. Ongaro, C. Pacchierotti, ChangKyu Yoon, D. Prattichizzo, D. Gracias, S. Misra

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引用次数: 22

Abstract

Current wireless, small-scale robots have restricted manipulation capabilities, and limited intuitive tools to control their motion. This paper presents a novel teleoperation system with haptic feedback for the control of untethered soft grippers. The system is able to move and open/close the grippers by regulating the magnetic field and temperature in the workspace. Users can intuitively control the grippers using a grounded haptic interface, that is also capable of providing compelling force feedback information as the gripper interacts with the environment. The magnetic closed-loop control algorithm is designed starting from a Finite Element Model analysis. The electromagnetic model used is validated by a measurement of the magnetic field with a resolution of 0.1 mT and sampling rate of 6.8×106 samples/m2. The system shows an accuracy in positioning the gripper of 0.08 mm at a velocity of 0.81 mm/s. The robustness of the control and tracking algorithms are tested by spraying the workspace with water drops that cause glares and related disturbances of up to 0.41 mm.

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一种具有触觉反馈的电磁系统，用于控制受干扰影响的无系软抓取器

目前的无线、小型机器人的操作能力有限，而且控制它们运动的直观工具也有限。提出了一种基于触觉反馈的无系软爪遥操作控制系统。该系统能够通过调节工作区的磁场和温度来移动和打开/关闭夹持器。用户可以使用接地触觉界面直观地控制抓手，当抓手与环境交互时，也能够提供引人注目的力反馈信息。从有限元模型分析出发，设计了磁闭环控制算法。通过0.1 mT的磁场测量和6.8×106样品/m2的采样率验证了电磁模型的有效性。该系统在0.81 mm/s的速度下，对夹持器的定位精度为0.08 mm。通过向工作空间喷射水滴来测试控制和跟踪算法的鲁棒性，水滴会产生高达0.41 mm的眩光和相关干扰。

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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2016 6th IEEE International Conference on Biomedical Robotics and Biomechatronics (BioRob)

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