Effect of Haptic Feedback From Self-Touch on Limb Movement Coordination
Identifieur interne : 000107 ( PascalFrancis/Corpus ); précédent : 000106; suivant : 000108Effect of Haptic Feedback From Self-Touch on Limb Movement Coordination
Auteurs : Julius Verrel ; Ulman Lindenberger ; Nobuhiro Hagura ; Patrick HaggardSource :
- Journal of experimental psychology. Human perception and performance [ 0096-1523 ] ; 2013.
Descripteurs français
- Pascal (Inist)
English descriptors
- KwdEn :
Abstract
Touching one's own body provides haptic feedback about the spatial configuration and movement of body parts. However, the influence of self-touch on movement performance has not been investigated so far. The authors evaluated the contribution of self-touch by asking participants to perform cyclic movement sequences with their feet while touching them with their hands, or vice versa. Hands and feet were either crossed or uncrossed (parallel), manipulating anatomical congruency of haptic feedback. The effects of self-touch (vs. object-touch), active limb (feet vs. hands) and sequence complexity were assessed in three separate experiments. Task performance was strongly and specifically disrupted in one of the anatomically incongruent conditions (hands-parallel/feet-crossed). This disruption occurred only with self-touch (Experiment 1), with the feet active (Experiment 2), and was more pronounced for the more complex movement sequence (Experiment 3). Thus, incongruent self-touch can strongly interfere with motor performance, showing that haptic information is automatically integrated in the online control of movement. The observed asymmetry between hands and feet indicates limb-specific differences regarding the use of spatial frames of reference and/or regarding the weighting of sensory information. The results emphasize the intimate connection between programming of action sequences and the anticipation of somatic feedback from self-touch.
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Pour connaître la documentation sur le format Inist Standard.
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Format Inist (serveur)
NO : | PASCAL 14-0015914 INIST |
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ET : | Effect of Haptic Feedback From Self-Touch on Limb Movement Coordination |
AU : | VERREL (Julius); LINDENBERGER (Ulman); HAGURA (Nobuhiro); HAGGARD (Patrick) |
AF : | Max Planck Institute for Human Development/Berlin/Allemagne (1 aut., 2 aut.); Institute of Cognitive Neuroscience, University College London/Royaume-Uni (3 aut., 4 aut.) |
DT : | Publication en série; Niveau analytique |
SO : | Journal of experimental psychology. Human perception and performance; ISSN 0096-1523; Coden JPHPDH; Etats-Unis; Da. 2013; Vol. 39; No. 6; Pp. 1775-1785; Bibl. 3/4 p. |
LA : | Anglais |
EA : | Touching one's own body provides haptic feedback about the spatial configuration and movement of body parts. However, the influence of self-touch on movement performance has not been investigated so far. The authors evaluated the contribution of self-touch by asking participants to perform cyclic movement sequences with their feet while touching them with their hands, or vice versa. Hands and feet were either crossed or uncrossed (parallel), manipulating anatomical congruency of haptic feedback. The effects of self-touch (vs. object-touch), active limb (feet vs. hands) and sequence complexity were assessed in three separate experiments. Task performance was strongly and specifically disrupted in one of the anatomically incongruent conditions (hands-parallel/feet-crossed). This disruption occurred only with self-touch (Experiment 1), with the feet active (Experiment 2), and was more pronounced for the more complex movement sequence (Experiment 3). Thus, incongruent self-touch can strongly interfere with motor performance, showing that haptic information is automatically integrated in the online control of movement. The observed asymmetry between hands and feet indicates limb-specific differences regarding the use of spatial frames of reference and/or regarding the weighting of sensory information. The results emphasize the intimate connection between programming of action sequences and the anticipation of somatic feedback from self-touch. |
CC : | 002A26E05; 002A26D04 |
FD : | Sensibilité tactile; Rétroaction; Soi; Coordination musculaire; Corps; Image corporelle; Contrôle moteur; Cognition; Motricité; Etude expérimentale; Homme |
FG : | Perception |
ED : | Tactile sensitivity; Feedback regulation; Self; Muscular coordination; Body; Body image; Motor control; Cognition; Motricity; Experimental study; Human |
EG : | Perception |
SD : | Sensibilidad tactil; Retroacción; Si mismo; Coordinación muscular; Cuerpo; Imagen corporal; Control motor; Cognición; Motricidad; Estudio experimental; Hombre |
LO : | INIST-3032D.354000501105280220 |
ID : | 14-0015914 |
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Pascal:14-0015914Le document en format XML
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<front><div type="abstract" xml:lang="en">Touching one's own body provides haptic feedback about the spatial configuration and movement of body parts. However, the influence of self-touch on movement performance has not been investigated so far. The authors evaluated the contribution of self-touch by asking participants to perform cyclic movement sequences with their feet while touching them with their hands, or vice versa. Hands and feet were either crossed or uncrossed (parallel), manipulating anatomical congruency of haptic feedback. The effects of self-touch (vs. object-touch), active limb (feet vs. hands) and sequence complexity were assessed in three separate experiments. Task performance was strongly and specifically disrupted in one of the anatomically incongruent conditions (hands-parallel/feet-crossed). This disruption occurred only with self-touch (Experiment 1), with the feet active (Experiment 2), and was more pronounced for the more complex movement sequence (Experiment 3). Thus, incongruent self-touch can strongly interfere with motor performance, showing that haptic information is automatically integrated in the online control of movement. The observed asymmetry between hands and feet indicates limb-specific differences regarding the use of spatial frames of reference and/or regarding the weighting of sensory information. The results emphasize the intimate connection between programming of action sequences and the anticipation of somatic feedback from self-touch.</div>
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