Add to ORKGThe brain can predict the location of a moving object to compensate for the delays caused by the processing of neural signals
Neural transmission latency would introduce a spatial lag when an object moves across the visual fie...
AbstractThe brain can predict and estimate motion based on visual translation. This paper addresses ...
Evidence for motion extrapolation at motion offset is scarce. In contrast, there is abundant evidenc...
The brain can predict the location of a moving object to compensate for the delays caused by the pro...
The transmission of visual signals from eye to brain involves considerable delays in conduction and ...
The transmission of visual signals from eye to brain involves considerable delays in conduction and ...
AbstractMoving objects change their position until signals from the photoreceptors arrive in the vis...
YesAn ability to predict the time-to-contact (TTC) of moving objects that become momentarily hidden ...
The flash-lag effect, in which a moving object is perceived ahead of a colocalized flash, has led to...
International audienceDue to its inherent neural delays, the visual system has an outdated access to...
The human brain is nearly constantly subjected to visual motion signals originating from a large var...
To intercept or avoid moving objects successfully, we must compensate for the sensorimotor delays as...
Humans can covertly track the position of an object, even if the object is temporarily occluded. Wha...
Hitting a baseball is often described as the most difficult thing to do in sports. A key aptitude of...
How the brain stores motion information and subsequently uses it to follow a moving target is largel...
Neural transmission latency would introduce a spatial lag when an object moves across the visual fie...
AbstractThe brain can predict and estimate motion based on visual translation. This paper addresses ...
Evidence for motion extrapolation at motion offset is scarce. In contrast, there is abundant evidenc...
The brain can predict the location of a moving object to compensate for the delays caused by the pro...
The transmission of visual signals from eye to brain involves considerable delays in conduction and ...
The transmission of visual signals from eye to brain involves considerable delays in conduction and ...
AbstractMoving objects change their position until signals from the photoreceptors arrive in the vis...
YesAn ability to predict the time-to-contact (TTC) of moving objects that become momentarily hidden ...
The flash-lag effect, in which a moving object is perceived ahead of a colocalized flash, has led to...
International audienceDue to its inherent neural delays, the visual system has an outdated access to...
The human brain is nearly constantly subjected to visual motion signals originating from a large var...
To intercept or avoid moving objects successfully, we must compensate for the sensorimotor delays as...
Humans can covertly track the position of an object, even if the object is temporarily occluded. Wha...
Hitting a baseball is often described as the most difficult thing to do in sports. A key aptitude of...
How the brain stores motion information and subsequently uses it to follow a moving target is largel...
Neural transmission latency would introduce a spatial lag when an object moves across the visual fie...
AbstractThe brain can predict and estimate motion based on visual translation. This paper addresses ...
Evidence for motion extrapolation at motion offset is scarce. In contrast, there is abundant evidenc...