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Multi-physics modelling and experimental validation of electrovibration based haptic devices

Teja Vodlak, Zlatko Vidrih, Eric Vezzoli, Betty Lemaire-Semail, Djordje Peric Orcid Logo

Biotribology, Volume: 8, Pages: 12 - 25

Swansea University Author: Djordje Peric Orcid Logo

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DOI (Published version): 10.1016/j.biotri.2016.09.001

Abstract

Electrovibration tactile displays exploit the polarisation of the finger pad, caused by an insulated high voltage supplied plate. This results in electrostatic attraction, which can be used to modulate the users' perception of an essentially flat surface and induce texture sensation. Two analyt...

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Published in: Biotribology
ISSN: 2352-5738
Published: 2016
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URI: https://cronfa.swan.ac.uk/Record/cronfa30313
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first_indexed 2016-10-03T13:07:24Z
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spelling 2016-11-28T11:02:03.2996165 v2 30313 2016-10-03 Multi-physics modelling and experimental validation of electrovibration based haptic devices 9d35cb799b2542ad39140943a9a9da65 0000-0002-1112-301X Djordje Peric Djordje Peric true false 2016-10-03 CIVL Electrovibration tactile displays exploit the polarisation of the finger pad, caused by an insulated high voltage supplied plate. This results in electrostatic attraction, which can be used to modulate the users' perception of an essentially flat surface and induce texture sensation. Two analytical models of electrovibration, based on parallel plate capacitor assumption, are demonstrably taken and assessed by comparisons with experimental results published in literature. In addition, an experimental setup was developed to measure the electrostatic force between the finger pad and a high voltage supplied plate in a static and out-of-contact state in order to support the use of parallel plate capacitor model. Development, validation, and application of a computational framework for modelling tactile scenarios on real and virtual surfaces rendered by electrovibration technique is presented. The framework incorporates fully parametric model in terms of materials and geometry of the finger pad, virtual and real surfaces, and can serve as a tool for virtual prototyping and haptic rendering in electrovibration tactile displays. This is achieved by controlling the applied voltage signal in order to guarantee similar lateral force cues in real and simulated surfaces. Journal Article Biotribology 8 12 25 2352-5738 31 12 2016 2016-12-31 10.1016/j.biotri.2016.09.001 COLLEGE NANME Civil Engineering COLLEGE CODE CIVL Swansea University 2016-11-28T11:02:03.2996165 2016-10-03T11:38:32.7831531 Faculty of Science and Engineering School of Aerospace, Civil, Electrical, General and Mechanical Engineering - Civil Engineering Teja Vodlak 1 Zlatko Vidrih 2 Eric Vezzoli 3 Betty Lemaire-Semail 4 Djordje Peric 0000-0002-1112-301X 5 0030313-03102016113950.pdf vodlak2016.pdf 2016-10-03T11:39:50.4870000 Output 3731167 application/pdf Accepted Manuscript true 2017-09-29T00:00:00.0000000 false
title Multi-physics modelling and experimental validation of electrovibration based haptic devices
spellingShingle Multi-physics modelling and experimental validation of electrovibration based haptic devices
Djordje Peric
title_short Multi-physics modelling and experimental validation of electrovibration based haptic devices
title_full Multi-physics modelling and experimental validation of electrovibration based haptic devices
title_fullStr Multi-physics modelling and experimental validation of electrovibration based haptic devices
title_full_unstemmed Multi-physics modelling and experimental validation of electrovibration based haptic devices
title_sort Multi-physics modelling and experimental validation of electrovibration based haptic devices
author_id_str_mv 9d35cb799b2542ad39140943a9a9da65
author_id_fullname_str_mv 9d35cb799b2542ad39140943a9a9da65_***_Djordje Peric
author Djordje Peric
author2 Teja Vodlak
Zlatko Vidrih
Eric Vezzoli
Betty Lemaire-Semail
Djordje Peric
format Journal article
container_title Biotribology
container_volume 8
container_start_page 12
publishDate 2016
institution Swansea University
issn 2352-5738
doi_str_mv 10.1016/j.biotri.2016.09.001
college_str Faculty of Science and Engineering
hierarchytype
hierarchy_top_id facultyofscienceandengineering
hierarchy_top_title Faculty of Science and Engineering
hierarchy_parent_id facultyofscienceandengineering
hierarchy_parent_title Faculty of Science and Engineering
department_str School of Aerospace, Civil, Electrical, General and Mechanical Engineering - Civil Engineering{{{_:::_}}}Faculty of Science and Engineering{{{_:::_}}}School of Aerospace, Civil, Electrical, General and Mechanical Engineering - Civil Engineering
document_store_str 1
active_str 0
description Electrovibration tactile displays exploit the polarisation of the finger pad, caused by an insulated high voltage supplied plate. This results in electrostatic attraction, which can be used to modulate the users' perception of an essentially flat surface and induce texture sensation. Two analytical models of electrovibration, based on parallel plate capacitor assumption, are demonstrably taken and assessed by comparisons with experimental results published in literature. In addition, an experimental setup was developed to measure the electrostatic force between the finger pad and a high voltage supplied plate in a static and out-of-contact state in order to support the use of parallel plate capacitor model. Development, validation, and application of a computational framework for modelling tactile scenarios on real and virtual surfaces rendered by electrovibration technique is presented. The framework incorporates fully parametric model in terms of materials and geometry of the finger pad, virtual and real surfaces, and can serve as a tool for virtual prototyping and haptic rendering in electrovibration tactile displays. This is achieved by controlling the applied voltage signal in order to guarantee similar lateral force cues in real and simulated surfaces.
published_date 2016-12-31T03:36:59Z
_version_ 1763751619106701312
score 11.01753

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