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New Steady-Hand Eye Robot with Micro-Force Sensing for Vitreoretinal Surgery.用于玻璃体视网膜手术的新型带微力传感的稳手眼机器人
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手持设备增强触觉感知的心理物理学评估

Psychophysical evaluation of haptic perception under augmentation by a handheld device.

作者信息

Wu Bing, Klatzky Roberta, Lee Randy, Shivaprabhu Vikas, Galeotti John, Siegel Mel, Schuman Joel S, Hollis Ralph, Stetten George

机构信息

Arizona State University, Mesa, Arizona

Carnegie Mellon University, Pittsburgh, Pennsylvania.

出版信息

Hum Factors. 2015 May;57(3):523-37. doi: 10.1177/0018720814551414. Epub 2014 Sep 26.

DOI:10.1177/0018720814551414
PMID:25875439
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4480420/
Abstract

OBJECTIVE

This study investigated the effectiveness of force augmentation in haptic perception tasks.

BACKGROUND

Considerable engineering effort has been devoted to developing force augmented reality (AR) systems to assist users in delicate procedures like microsurgery. In contrast, far less has been done to characterize the behavioral outcomes of these systems, and no research has systematically examined the impact of sensory and perceptual processes on force augmentation effectiveness.

METHOD

Using a handheld force magnifier as an exemplar haptic AR, we conducted three experiments to characterize its utility in the perception of force and stiffness. Experiments 1 and 2 measured, respectively, the user's ability to detect and differentiate weak force (<0.5 N) with or without the assistance of the device and compared it to direct perception. Experiment 3 examined the perception of stiffness through the force augmentation.

RESULTS

The user's ability to detect and differentiate small forces was significantly improved by augmentation at both threshold and suprathreshold levels. The augmentation also enhanced stiffness perception. However, although perception of augmented forces matches that of the physical equivalent for weak forces, it falls off with increasing intensity.

CONCLUSION

The loss in the effectiveness reflects the nature of sensory and perceptual processing. Such perceptual limitations should be taken into consideration in the design and development of haptic AR systems to maximize utility.

APPLICATION

The findings provide useful information for building effective haptic AR systems, particularly for use in microsurgery.

摘要

目的

本研究调查了力增强在触觉感知任务中的有效性。

背景

大量工程努力致力于开发力增强现实(AR)系统,以协助用户进行诸如显微手术等精细操作。相比之下,对这些系统的行为结果进行表征的工作要少得多,并且没有研究系统地考察感觉和知觉过程对力增强有效性的影响。

方法

使用手持式力放大器作为典型的触觉AR,我们进行了三项实验来表征其在力和刚度感知中的效用。实验1和实验2分别测量了用户在有或没有该设备辅助的情况下检测和区分弱力(<0.5 N)的能力,并将其与直接感知进行比较。实验3通过力增强来考察刚度感知。

结果

在阈值和阈上水平,力增强都显著提高了用户检测和区分小力的能力。力增强还增强了刚度感知。然而,尽管对于弱力,增强力的感知与物理等效力的感知相匹配,但随着强度增加,这种匹配会减弱。

结论

有效性的损失反映了感觉和知觉处理的本质。在触觉AR系统的设计和开发中应考虑这种知觉限制,以实现效用最大化。

应用

这些发现为构建有效的触觉AR系统提供了有用信息,特别是在显微手术中的应用。