Creating widely accessible spatial interfaces: mobile VR for managing persistent pain.
Identifieur interne : 002426 ( PubMed/Checkpoint ); précédent : 002425; suivant : 002427Creating widely accessible spatial interfaces: mobile VR for managing persistent pain.
Auteurs : David Schroeder ; Fedor Korsakov ; Joseph Jolton ; Francis J. Keefe ; Alex Haley ; Daniel F. KeefeSource :
- IEEE computer graphics and applications [ 1558-1756 ]
English descriptors
- KwdEn :
- MESH :
- methods : Pain Management.
- Humans, User-Computer Interface.
Abstract
Using widely accessible VR technologies, researchers have implemented a series of multimodal spatial interfaces and virtual environments. The results demonstrate the degree to which we can now use low-cost (for example, mobile-phone based) VR environments to create rich virtual experiences involving motion sensing, physiological inputs, stereoscopic imagery, sound, and haptic feedback. Adapting spatial interfaces to these new platforms can open up exciting application areas for VR. In this case, the application area was in-home VR therapy for patients suffering from persistent pain (for example, arthritis and cancer pain). For such therapy to be successful, a rich spatial interface and rich visual aesthetic are particularly important. So, an interdisciplinary team with expertise in technology, design, meditation, and the psychology of pain collaborated to iteratively develop and evaluate several prototype systems. The video at http://youtu.be/mMPE7itReds demonstrates how the sine wave fitting responds to walking motions, for a walking-in-place application.
DOI: 10.1109/MCG.2013.38
PubMed: 24807994
Affiliations:
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pubmed:24807994Le document en format XML
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The results demonstrate the degree to which we can now use low-cost (for example, mobile-phone based) VR environments to create rich virtual experiences involving motion sensing, physiological inputs, stereoscopic imagery, sound, and haptic feedback. Adapting spatial interfaces to these new platforms can open up exciting application areas for VR. In this case, the application area was in-home VR therapy for patients suffering from persistent pain (for example, arthritis and cancer pain). For such therapy to be successful, a rich spatial interface and rich visual aesthetic are particularly important. So, an interdisciplinary team with expertise in technology, design, meditation, and the psychology of pain collaborated to iteratively develop and evaluate several prototype systems. 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Keefe</name><name sortKey="Keefe, Francis J" sort="Keefe, Francis J" uniqKey="Keefe F" first="Francis J" last="Keefe">Francis J. Keefe</name><name sortKey="Korsakov, Fedor" sort="Korsakov, Fedor" uniqKey="Korsakov F" first="Fedor" last="Korsakov">Fedor Korsakov</name><name sortKey="Schroeder, David" sort="Schroeder, David" uniqKey="Schroeder D" first="David" last="Schroeder">David Schroeder</name></noCountry></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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