Calibrating reach distance to visual targets
Identifieur interne : 000B37 ( PascalFrancis/Corpus ); précédent : 000B36; suivant : 000B38Calibrating reach distance to visual targets
Auteurs : Mark Mon-Williams ; Geoffrey P. BinghamSource :
- Journal of experimental psychology. Human perception and performance [ 0096-1523 ] ; 2007.
Descripteurs français
- Pascal (Inist)
English descriptors
- KwdEn :
Abstract
The authors investigated the calibration of reach distance by gradually distorting the haptic feedback obtained when participants grasped visible target objects. The authors found that the modified relationship between visually specified distance and reach distance could be captured by a straight-line mapping function. Thus, the relation could be described using 2 parameters: bias and slope. The authors investigated whether calibration generalized across reach space with respect to changes in bias and slope. In Experiment 1, the authors showed that both bias and slope recalibrate. In Experiment 2, they tested the symmetries of reach space with respect to changes in bias. They discovered that reach space is asymmetric, with the bias shifting inward more readily than outward. The authors measured how rapidly the system calibrated and the stability of calibration once feedback was removed. In Experiment 3, they showed that bias and slope can be calibrated independently of one another. In Experiment 4, the authors showed that these calibration effects are not cognitively penetrable.
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Pour connaître la documentation sur le format Inist Standard.
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Format Inist (serveur)
| NO : | PASCAL 07-0313210 INIST |
|---|---|
| ET : | Calibrating reach distance to visual targets |
| AU : | MON-WILLIAMS (Mark); BINGHAM (Geoffrey P.) |
| AF : | University of Aberdeen/Royaume-Uni (1 aut.); Indiana University Bloomington/Etats-Unis (2 aut.) |
| DT : | Publication en série; Niveau analytique |
| SO : | Journal of experimental psychology. Human perception and performance; ISSN 0096-1523; Coden JPHPDH; Etats-Unis; Da. 2007; Vol. 33; No. 3; Pp. 645-656; Bibl. 3/4 p. |
| LA : | Anglais |
| EA : | The authors investigated the calibration of reach distance by gradually distorting the haptic feedback obtained when participants grasped visible target objects. The authors found that the modified relationship between visually specified distance and reach distance could be captured by a straight-line mapping function. Thus, the relation could be described using 2 parameters: bias and slope. The authors investigated whether calibration generalized across reach space with respect to changes in bias and slope. In Experiment 1, the authors showed that both bias and slope recalibrate. In Experiment 2, they tested the symmetries of reach space with respect to changes in bias. They discovered that reach space is asymmetric, with the bias shifting inward more readily than outward. The authors measured how rapidly the system calibrated and the stability of calibration once feedback was removed. In Experiment 3, they showed that bias and slope can be calibrated independently of one another. In Experiment 4, the authors showed that these calibration effects are not cognitively penetrable. |
| CC : | 002A26E03; 002A26E05; 002A26D04 |
| FD : | Vision; Perception espace; Cognition; Motricité; Mouvement corporel; Membre supérieur; Préhension; Sensibilité tactile; Distance stimulus; Etude expérimentale; Homme |
| ED : | Vision; Space perception; Cognition; Motricity; Body movement; Upper limb; Gripping; Tactile sensitivity; Stimulus distance; Experimental study; Human |
| SD : | Visión; Percepción espacio; Cognición; Motricidad; Movimiento corporal; Miembro superior; Prension; Sensibilidad tactil; Distancia estímulo; Estudio experimental; Hombre |
| LO : | INIST-3032D.354000162342220090 |
| ID : | 07-0313210 |
Links to Exploration step
Pascal:07-0313210Le document en format XML
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The authors found that the modified relationship between visually specified distance and reach distance could be captured by a straight-line mapping function. Thus, the relation could be described using 2 parameters: bias and slope. The authors investigated whether calibration generalized across reach space with respect to changes in bias and slope. In Experiment 1, the authors showed that both bias and slope recalibrate. In Experiment 2, they tested the symmetries of reach space with respect to changes in bias. They discovered that reach space is asymmetric, with the bias shifting inward more readily than outward. The authors measured how rapidly the system calibrated and the stability of calibration once feedback was removed. In Experiment 3, they showed that bias and slope can be calibrated independently of one another. 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Human perception and performance; ISSN 0096-1523; Coden JPHPDH; Etats-Unis; Da. 2007; Vol. 33; No. 3; Pp. 645-656; Bibl. 3/4 p.</SO><LA>Anglais</LA><EA>The authors investigated the calibration of reach distance by gradually distorting the haptic feedback obtained when participants grasped visible target objects. The authors found that the modified relationship between visually specified distance and reach distance could be captured by a straight-line mapping function. Thus, the relation could be described using 2 parameters: bias and slope. The authors investigated whether calibration generalized across reach space with respect to changes in bias and slope. In Experiment 1, the authors showed that both bias and slope recalibrate. In Experiment 2, they tested the symmetries of reach space with respect to changes in bias. They discovered that reach space is asymmetric, with the bias shifting inward more readily than outward. 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