Soft-Material-Based Highly Reliable Tri-Axis Tactile Thin-Film Sensors for Robotic Manipulation Tasks

2021 IEEE Sensors Pub Date : 2021-10-31 DOI:10.1109/SENSORS47087.2021.9639695

K. Tsukamoto, A. Ebisui, T. Goto, Yoshiaki Sakakura, Ken Kobayashi, Satoshi Sato, T. Kamei, Yutaka Imai, K. Nomoto

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Abstract

Tactile sensing is essential for intelligent robot control such as for dexterous manipulation tasks. To provide reliable sensors that can withstand industrial applications, we have developed a soft and thin-film tactile sensor capable of detecting tri-axis force components including normal and shear forces. The thickness of the sensor is 5.5 mm, and the sensor can be easily attached on an end-effector. Two layers of capacitive-sensing-electrode arrays sandwiching an elastomer layer of 2-mm spatial resolution are embedded in soft material, and output signals are distributed. To measure the external force vector, center-of-distributed-signal calculation was conducted. Our sensor exhibited linear behavior within 0.1 to 10 N for normal force and 0.1 to 4 N for shear force. With high reliability, sensor sensitivity did not change over ±10.0% even after one million repetitive keystroke cycles and one million repetitive shear-movement cycles. To determine the sensor’s effectiveness for manipulation tasks, a grasping-force control experiment was conducted using sensor signal feedback, and multiple local-shear-force vectors were successfully calculated using area-divided methods.

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用于机器人操作任务的基于软材料的高可靠三轴触觉薄膜传感器

触觉感知是智能机器人控制的关键，如灵巧的操作任务。为了提供能够承受工业应用的可靠传感器，我们开发了一种柔软的薄膜触觉传感器，能够检测三轴力组件，包括法向力和剪力。传感器的厚度为5.5毫米，传感器可以很容易地附着在末端执行器上。将两层电容传感电极阵列夹在空间分辨率为2mm的弹性体层中嵌入软质材料，并对输出信号进行分布。为了测量外力矢量，进行了分布信号中心计算。我们的传感器在0.1至10牛的法向力和0.1至4牛的剪切力范围内表现出线性行为。具有高可靠性，即使在100万次重复击键周期和100万次重复剪切运动周期后，传感器灵敏度的变化也不会超过±10.0%。为了确定传感器对操作任务的有效性，利用传感器信号反馈进行了抓取力控制实验，并采用面积分割法成功计算了多个局部剪切力矢量。

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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2021 IEEE Sensors

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