Internal models and prediction of visual gravitational motion.
about
Visual gravitational motion and the vestibular system in humans.Predictive eye movements in natural vision.Neural extrapolation of motion for a ball rolling down an inclined planeCatching a ball at the right time and place: individual factors matterCatching what we can't see: manual interception of occluded fly-ball trajectories.How Fast Do Objects Fall in Visual Memory? Uncovering the Temporal and Spatial Features of Representational Gravity.Hand interception of occluded motion in humans: a test of model-based vs. on-line controlSpatiotemporal characteristics of muscle patterns for ball catchingHow Can People Be so Good at Intercepting Accelerating Objects if They Are so Poor at Visually Judging Acceleration?Computation of linear acceleration through an internal model in the macaque cerebellumDirection-dependent arm kinematics reveal optimal integration of gravity cues.On-line and model-based approaches to the visual control of action.Filling gaps in visual motion for target capture.Gravity as a Strong Prior: Implications for Perception and Action.Synergies between optical and physical variables in intercepting parabolic targetsThe visual representations of motion and of gravity are functionally independent: Evidence of a differential effect of smooth pursuit eye movements.Where Are You Throwing the Ball? I Better Watch Your Body, Not Just Your Arm!Perceptual weight judgments when viewing one's own and others' movements under minimalist conditions of visual presentation.Differential contributions to the interception of occluded ballistic trajectories by the temporoparietal junction, area hMT/V5+, and the intraparietal cortex.A novel dissociation between representational momentum and representational gravity through response modality.Intercepting virtual balls approaching under different gravity conditions: evidence for spatial prediction.A new paradigm for human stick balancing: a suspended not an inverted pendulum.Eye movements and manual interception of ballistic trajectories: effects of law of motion perturbations and occlusions.Familiar trajectories facilitate the interpretation of physical forces when intercepting a moving target.Vestibular stimulation interferes with the dynamics of an internal representation of gravity.Perceptual and motor learning underlies human stick-balancing skill.Influence of practice with within-trials and inter-trials changes of target velocity in improving movement correction.Prospective versus predictive control in timing of hitting a falling ball.Non-predictive online spatial coding in the posterior parietal cortex when aiming ahead for catching.Audio-tactile cues from an object's fall change estimates of one's body height.Rolling Motion Along an Incline: Visual Sensitivity to the Relation Between Acceleration and Slope.
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Internal models and prediction of visual gravitational motion.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 21 May 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Internal models and prediction of visual gravitational motion.
@en
Internal models and prediction of visual gravitational motion.
@nl
type
label
Internal models and prediction of visual gravitational motion.
@en
Internal models and prediction of visual gravitational motion.
@nl
prefLabel
Internal models and prediction of visual gravitational motion.
@en
Internal models and prediction of visual gravitational motion.
@nl
P50
P1433
P1476
Internal models and prediction of visual gravitational motion
@en
P2093
Patrice Senot
P304
P356
10.1016/J.VISRES.2008.04.005
P577
2008-05-21T00:00:00Z