Alaa Adel, M. Seif, Gerold Hölzl, M. Kranz, Slim Abdennadher, I. Khalil
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引用次数: 7
摘要
在这项研究中,我们开发了一种基于电磁的触觉界面,通过可穿戴的触觉设备(具有单偶极矩的骨科手指夹板)向操作员提供可控的磁力,而不需要位置反馈。首先,我们对附着在可穿戴触觉设备上的单个磁偶极子施加的电磁力进行了建模,并推导了偶极矩的磁力-电流映射。其次,将该映射作为触觉界面电磁线圈、可穿戴触觉设备偶极矩和系统工作空间参数选择的依据。基于电磁的触觉界面可以使用超过50 mN的磁力,在150 mm × 150 mm × 20 mm的工作空间内,在半空中绘制三维(3D)虚拟物体。实验证明,参与者在区分4个代表性3D虚拟物体的几何形状方面的成功率为61%。然而,我们的统计分析表明,在95%的置信水平上,参与者区分几何形状的能力在统计上并不显著。
Rendering 3D virtual objects in mid-air using controlled magnetic fields
In this study, we develop an electromagnetic-based haptic interface to provide controlled magnetic forces to the operator through a wearable haptic device (an orthopedic finger splint with single dipole moment) without position feedback. First, we model the electromagnetic forces exerted on a single magnetic dipole attached to the wearable haptic device, and derive magnetic force-current mapping for the dipole moment. Second, this mapping is used as basis for parameter selection of the electromagnetic coils of the haptic interface, dipole moment of the wearable haptic device, and the operating workspace of the system. The electromagnetic-based haptic interface enables three-dimensional (3D) virtual object rendering in mid-air within a workspace of 150 mm × 150 mm × 20 mm, using magnetic forces in excess of 50 mN. Participants experimentally demonstrate a 61% success rate in distinguishing the geometry of 4 representative 3D virtual objects. However, our statistical analysis shows that the ability of the participants to distinguish between geometries is not statistically significant, for 95% confidence level.
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