Add to ORKGHoward (2012) published very similar studies using the motion aftereffect to probe the way in which motion through depth is computed. Here, we compare and contrast the findings of these two studies and incorporate their results with a brief follow-up experiment. Taken together, the results leave no doubt that the human visual system incorporates a mechanism that is uniquely sensitive to the difference in velocity signals between the two eyes, but—perhaps surprisingly—evidence for a neural representation of changes in binocular disparity over time remains elusive
There are two binocular cues of motion in depth: the interocular velocity difference (IOVD) and chan...
Purpose: Two binocular sources of information serve motion-in-depth (MID) perception: changes in dis...
There are in principle at least two binocular sources of information that could be used to determine...
AbstractChanging disparity (CD) and interocular velocity difference (IOVD) are two possible mechanis...
AbstractChanging disparity (CD) and interocular velocity difference (IOVD) are two possible mechanis...
AbstractThere are two possible binocular mechanisms for the detection of motion in depth. One is bas...
AbstractAn object moving in depth produces retinal images that change in position over time by diffe...
Motion-in-depth can be detected by using two different types of binocular cues: change of disparity ...
When an object moves in three dimensions, the two eyes' views of the world deliver slightly differen...
There are two ways to detect a displacement in stereoscopic depth, namely by monitoring the change i...
Motion-in-depth can be detected by using two different types of binocular cues: change of disparity ...
Motion-in-depth can be detected by using two different types of binocular cues: change of disparity ...
AbstractTwo different binocular cues are known for detecting motion in depth. One is disparity chang...
Purpose: Two binocular sources of information serve motion-in-depth (MID) perception: changes in dis...
Under a variety of conditions, motion in depth from binocular cues is harder to detect than lateral ...
There are two binocular cues of motion in depth: the interocular velocity difference (IOVD) and chan...
Purpose: Two binocular sources of information serve motion-in-depth (MID) perception: changes in dis...
There are in principle at least two binocular sources of information that could be used to determine...
AbstractChanging disparity (CD) and interocular velocity difference (IOVD) are two possible mechanis...
AbstractChanging disparity (CD) and interocular velocity difference (IOVD) are two possible mechanis...
AbstractThere are two possible binocular mechanisms for the detection of motion in depth. One is bas...
AbstractAn object moving in depth produces retinal images that change in position over time by diffe...
Motion-in-depth can be detected by using two different types of binocular cues: change of disparity ...
When an object moves in three dimensions, the two eyes' views of the world deliver slightly differen...
There are two ways to detect a displacement in stereoscopic depth, namely by monitoring the change i...
Motion-in-depth can be detected by using two different types of binocular cues: change of disparity ...
Motion-in-depth can be detected by using two different types of binocular cues: change of disparity ...
AbstractTwo different binocular cues are known for detecting motion in depth. One is disparity chang...
Purpose: Two binocular sources of information serve motion-in-depth (MID) perception: changes in dis...
Under a variety of conditions, motion in depth from binocular cues is harder to detect than lateral ...
There are two binocular cues of motion in depth: the interocular velocity difference (IOVD) and chan...
Purpose: Two binocular sources of information serve motion-in-depth (MID) perception: changes in dis...
There are in principle at least two binocular sources of information that could be used to determine...