The small differences between the images formed in our left and right eyes are an important cue to the three-dimensional structure of scenes. These disparities are encoded by binocular neurons in the visual cortex. At the earliest stage of processing, these respond to binocular correlation between images. We assessed the perception of depth in anticorrelated stimuli, in which the contrast polarity in one eye is reversed, as a function of their location in the retinal image, and their depth configuration (a horizontal edge or a circle surrounded by an annulus) We found that, regardless of stimulus eccentricity, participants perceived depth in the natural direction for edge stimuli, and weakened, reversed depth for circular stimuli
In a random-dot stereogram (RDS), the percept of object surfaces in a three-dimensional scene is gen...
AbstractRecent studies show how single neurons detect binocular disparities. But how these signals a...
AbstractOur ability to see the world in depth is a major accomplishment of the brain. Previous model...
The binocular energy model of neural responses predicts that depth from binocular disparity might be...
In a random-dot stereogram (RDS), the spatial disparities between the interocularly corresponding bl...
In a random-dot stereogram, the percept of object surfaces in a three-dimensional scene is generated...
In a random dot stereogram (RDS), object surfaces in a three-dimensional scene are generated by imag...
Abstract The binocular energy model of neural responses predicts that depth from binocular disparity...
In a random-dot stereogram (RDS), depth percepts of object surfaces are generated using left-eye and...
This work was supported by the School of Psychology, University of St Andrews.One of the greatest ch...
One of the greatest challenges in visual neuroscience is that of linking neural activity with percep...
AbstractIn order to understand the role of oblique retinal image disparities in the perception of st...
AbstractStereoscopic vision requires the correspondence problem to be solved, i.e., discarding “fals...
In contrast-reversed random-dot stereograms (CRRDSs), a black dot in one eye matches a white dot in ...
Visual images from the two eyes are transmitted to the brain. Because the eyes are horizontally sepa...
In a random-dot stereogram (RDS), the percept of object surfaces in a three-dimensional scene is gen...
AbstractRecent studies show how single neurons detect binocular disparities. But how these signals a...
AbstractOur ability to see the world in depth is a major accomplishment of the brain. Previous model...
The binocular energy model of neural responses predicts that depth from binocular disparity might be...
In a random-dot stereogram (RDS), the spatial disparities between the interocularly corresponding bl...
In a random-dot stereogram, the percept of object surfaces in a three-dimensional scene is generated...
In a random dot stereogram (RDS), object surfaces in a three-dimensional scene are generated by imag...
Abstract The binocular energy model of neural responses predicts that depth from binocular disparity...
In a random-dot stereogram (RDS), depth percepts of object surfaces are generated using left-eye and...
This work was supported by the School of Psychology, University of St Andrews.One of the greatest ch...
One of the greatest challenges in visual neuroscience is that of linking neural activity with percep...
AbstractIn order to understand the role of oblique retinal image disparities in the perception of st...
AbstractStereoscopic vision requires the correspondence problem to be solved, i.e., discarding “fals...
In contrast-reversed random-dot stereograms (CRRDSs), a black dot in one eye matches a white dot in ...
Visual images from the two eyes are transmitted to the brain. Because the eyes are horizontally sepa...
In a random-dot stereogram (RDS), the percept of object surfaces in a three-dimensional scene is gen...
AbstractRecent studies show how single neurons detect binocular disparities. But how these signals a...
AbstractOur ability to see the world in depth is a major accomplishment of the brain. Previous model...