Sensory substitution using tactile pin arrays : Human factors, technology and applications : Multimodal human-computer interfaces
Identifieur interne : 000C27 ( PascalFrancis/Corpus ); précédent : 000C26; suivant : 000C28Sensory substitution using tactile pin arrays : Human factors, technology and applications : Multimodal human-computer interfaces
Auteurs : Steven A. Wall ; Stephen BrewsterSource :
- Signal processing [ 0165-1684 ] ; 2006.
Descripteurs français
- Pascal (Inist)
English descriptors
- KwdEn :
Abstract
Tactile arrays use a matrix of individually controllable elements to present spatial and temporal patterns of cutaneous information. Early devices of this type were in the field of sensory substitution to replace vision or hearing for users with a sensory impairment. Many advances have been made due to the appropriation of tactile displays for telerobotics and virtual reality, to represent physical contact with a remote or simulated environment. However, many of these have been limited to engineering prototypes. The recent commercial availability of affordable, portable tactile pin arrays has provided renewed impetus to apply the technology to sensory substitution applications. Lack of access to digitally stored data can prove a significant barrier to blind people seeking careers in numerate disciplines. Tactile displays could potentially provide a discrete and portable means of accessing graphical information in an intuitive non-visual manner. Results are presented from experiments on tactual perception related to understanding graphs and simple visualisations with a commercially available tactile array device. It was found that subjects could discriminate positive or negative line gradient to within ±4.7° of the horizontal, compared to ±3.25° for results with a force feedback mouse and ±2.42° with a raised paper representation.
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Format Inist (serveur)
| NO : | PASCAL 06-0499319 INIST |
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| ET : | Sensory substitution using tactile pin arrays : Human factors, technology and applications : Multimodal human-computer interfaces |
| AU : | WALL (Steven A.); BREWSTER (Stephen) |
| AF : | Glasgow Interactive Systems Group, Department of Computing Science, University of Glasgow, 17 Lilybank/Gardens, G12 8QQ/Royaume-Uni (1 aut., 2 aut.) |
| DT : | Publication en série; Niveau analytique |
| SO : | Signal processing; ISSN 0165-1684; Coden SPRODR; Pays-Bas; Da. 2006; Vol. 86; No. 12; Pp. 3674-3695; Bibl. 100 ref. |
| LA : | Anglais |
| EA : | Tactile arrays use a matrix of individually controllable elements to present spatial and temporal patterns of cutaneous information. Early devices of this type were in the field of sensory substitution to replace vision or hearing for users with a sensory impairment. Many advances have been made due to the appropriation of tactile displays for telerobotics and virtual reality, to represent physical contact with a remote or simulated environment. However, many of these have been limited to engineering prototypes. The recent commercial availability of affordable, portable tactile pin arrays has provided renewed impetus to apply the technology to sensory substitution applications. Lack of access to digitally stored data can prove a significant barrier to blind people seeking careers in numerate disciplines. Tactile displays could potentially provide a discrete and portable means of accessing graphical information in an intuitive non-visual manner. Results are presented from experiments on tactual perception related to understanding graphs and simple visualisations with a commercially available tactile array device. It was found that subjects could discriminate positive or negative line gradient to within ±4.7° of the horizontal, compared to ±3.25° for results with a force feedback mouse and ±2.42° with a raised paper representation. |
| CC : | 001D03J03 |
| FD : | Facteur humain; Téléopération; Réalité virtuelle; Prototype; Disponibilité; Capteur tactile; Interface haptique; Interface utilisateur; Interface multimodale; Dialogue homme machine |
| ED : | Human factor; Remote operation; Virtual reality; Prototype; Availability; Tactile sensor; Haptic interfaces; User interface; Multimodal interface; Man machine dialogue |
| SD : | Factor humano; Teleacción; Realidad virtual; Prototipo; Disponibilidad; Sensor tactil; Interfase usuario; Interfaz multimodal; Diálogo hombre máquina |
| LO : | INIST-18015.354000139231810100 |
| ID : | 06-0499319 |
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Pascal:06-0499319Le document en format XML
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