Design of a Wearable Fingertip Haptic Device for Remote Palpation: Characterisation and Interface with a Virtual Environment

Tzemanaki, Antonia; Al, Gorkem Anil; Melhuish, Chris; Dogramadzi, Sanja

doi:10.3389/frobt.2018.00062

Cited by 28 publications

(16 citation statements)

References 35 publications

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“…One of the subsystems comprises an inertial measurement unit that tracks the motion of user's finger and controls linear displacement of a pad towards one's fingertip. The other subsystem controls pressure in a variable compliance platform through a motorized syringe to simulate the stiffness of a touched surface (Tzemanaki et al, 2018).…”

Section: -Wearable Fingertip Haptic Device For Remote Palpation: Char...mentioning

confidence: 99%

Development of a wearable force-feedback mechanism for free-range haptic immersive experience

Kudry

Cohen

2022

Front. Virtual Real.

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The recent rise in popularity of head-mounted displays (HMDs) for immersion into virtual reality has resulted in demand for new ways to interact with virtual objects. Most solutions utilize generic controllers for interaction within virtual environments and provide limited haptic feedback. We describe the construction and implementation of an ambulatory (allowing walking) haptic feedback stylus with primary use in computer-aided design. Our stylus is a modified 3D Systems Touch force-feedback arm mounted on a wearable platform carried in front of a user. The wearable harness also holds a full-sized laptop, which drives the Meta Quest 2 HMD that is also worn by the user. This design provides six degrees-of-freedom without tethered limitations, while ensuring a high precision of force-feedback from virtual interaction. Our solution also provides an experience wherein a mobile user can explore different haptic feedback simulations and create, arrange, and deform general shapes.

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Section: -Wearable Fingertip Haptic Device For Remote Palpation: Char...mentioning

confidence: 99%

Development of a wearable force-feedback mechanism for free-range haptic immersive experience

Kudry

Cohen

2022

Front. Virtual Real.

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“…Consequently, several high-fidelity haptic feedback 26 devices have been developed for use in conjunction with remote surgical systems. One simple format is a stimulation device that can be placed directly on top of the fingertip or wrapped around the control joystick 27 and delivers a local vibration or compression 28 . In contrast, the most elaborate devices morph 2D surfaces to deliver tactile feedback by changing the surface’s geometry 29 – 31 .…”

Section: Introductionmentioning

confidence: 99%

Face mediated human–robot interaction for remote medical examination

Lalitharatne

Costi

Hashem

et al. 2022

Sci Rep

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Realtime visual feedback from consequences of actions is useful for future safety-critical human–robot interaction applications such as remote physical examination of patients. Given multiple formats to present visual feedback, using face as feedback for mediating human–robot interaction in remote examination remains understudied. Here we describe a face mediated human–robot interaction approach for remote palpation. It builds upon a robodoctor–robopatient platform where user can palpate on the robopatient to remotely control the robodoctor to diagnose a patient. A tactile sensor array mounted on the end effector of the robodoctor measures the haptic response of the patient under diagnosis and transfers it to the robopatient to render pain facial expressions in response to palpation forces. We compare this approach against a direct presentation of tactile sensor data in a visual tactile map. As feedback, the former has the advantage of recruiting advanced human capabilities to decode expressions on a human face whereas the later has the advantage of being able to present details such as intensity and spatial information of palpation. In a user study, we compare these two approaches in a teleoperated palpation task to find the hard nodule embedded in the remote abdominal phantom. We show that the face mediated human–robot interaction approach leads to statistically significant improvements in localizing the hard nodule without compromising the nodule position estimation time. We highlight the inherent power of facial expressions as communicative signals to enhance the utility and effectiveness of human–robot interaction in remote medical examinations.

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“…Magneto-Rheological (MR) fluid [16] and phase-change material [17] have the advantages of physical simulation accuracy but need complex control conditions. Pneumatic inflation, on the other hand, is compact in control and flexible to be integrated into diverse systems [18]. However, the elastomeric material is prone to exhibit non-linear deformation when stiffness is controlled [19].…”

Section: Introductionmentioning

confidence: 99%

An Abdominal Phantom With Tunable Stiffness Nodules and Force Sensing Capability for Palpation Training

Herzig

Lusignan

et al. 2021

IEEE Trans. Robot.

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Design of a Wearable Fingertip Haptic Device for Remote Palpation: Characterisation and Interface with a Virtual Environment

Cited by 28 publications

References 35 publications

Development of a wearable force-feedback mechanism for free-range haptic immersive experience

Development of a wearable force-feedback mechanism for free-range haptic immersive experience

Face mediated human–robot interaction for remote medical examination

An Abdominal Phantom With Tunable Stiffness Nodules and Force Sensing Capability for Palpation Training

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