Force variability during surface contact with bare finger or rigid probe

12th International Symposium on Haptic Interfaces for Virtual Environment and Teleoperator Systems, 2004. HAPTICS '04. Proceedings. Pub Date : 2004-03-27 DOI:10.1109/HAPTIC.2004.1287191

S. Lederman, R. Howe, R. Klatzky, C. Hamilton

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引用次数: 24

Abstract

The current study evaluated subjects' ability to control finger force during contact with a smooth plate. They were instructed to maintain a constant "light" or "medium" force when statically contacting the surface or when moving the end effector (finger or rigid probe) back and forth at 20 or 222 mm/s. Subjects pressed harder when using the probe (cf. finger) and during static contact (cf. both motion conditions). Conversely, the coefficient of variation for force (standard deviation/mean) was smallest for static conditions and when the probe is used. Force variability proved to be relatively high in the current experimental conditions, which are typically used during texture discrimination. Despite such variability, psychophysical research has shown that texture discrimination is in fact excellent. This finding markedly contrasts with grasping tasks, where both force control and outcome measures are excellent. We consider a number of implications of these results.

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裸露手指或刚性探针接触表面时的力变化

目前的研究评估了受试者在接触光滑板时控制手指力量的能力。他们被要求在静态接触表面或以20或222毫米/秒的速度来回移动末端执行器(手指或刚性探头)时保持恒定的“轻”或“中等”力。受试者在使用探针时(如手指)和在静态接触时(如两种运动条件下)用力按压。相反，力的变异系数(标准差/平均值)在静态条件下和使用探针时最小。在当前的实验条件下，力变异性被证明是相对较高的，这通常用于纹理识别。尽管存在这样的差异，心理物理学研究表明，纹理辨别实际上是非常出色的。这一发现与抓握任务形成鲜明对比，抓握任务的力控制和结果测量都很好。我们考虑了这些结果的一些含义。

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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12th International Symposium on Haptic Interfaces for Virtual Environment and Teleoperator Systems, 2004. HAPTICS '04. Proceedings.

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