An object moving through three-dimensional (3D) space typically yields different patterns of
velocities in each eye. For an interocular velocity difference cue to be used, some instances …

The visual system uses interocular velocity differences (IOVDs) to compute three-
dimensional (3D) motion. In most models, the monocular 2D motion signals are extracted …

The movement of an object toward or away from the head is perhaps the most critical piece
of information an organism can extract from its environment. Such 3D motion produces …

When an object is tracked with the eyes, veridical perception of the motion of that object and
other objects requires the brain to take account of and compensate for the eye movement …

Although extensive research investigates the encoding of both two-dimensional motion and
binocular disparity, relatively little is known about how the human visual system combines …

Accurate motion perception requires that the visual system integrate the 2D retinal motion
signals received by the two eyes into a single representation of 3D motion. However, most …

Two primary binocular cues—based on velocities seen by the two eyes or on temporal
changes in binocular disparity—support the perception of three-dimensional (3D) motion …

Two binocular cues are thought to underlie the visual perception of three-dimensional (3D)
motion: a disparity-based cue, which relies on changes in disparity over time, and a velocity …

Motion aftereffects are historically considered evidence for neuronal populations tuned to
specific directions of motion. Despite a wealth of motion aftereffect studies investigating 2D …

We investigated how the mechanism for perceiving motion-in-depth based on interocular
velocity differences (IOVDs) integrates signals from the motion spatial frequency (SF) …