Although binocular neurons in the primary visual cortex are sensitive to retinal disparity, their activity does not constitute an unambiguous disparity signal. A multi-spatial-scale neural model for disparity computation is developed to examine how population activity might be interpreted to overcome ambiguities at the single neuron level. The model incorporates a front end that encodes disparity by a family of complex cell-like energy units and a second stage that reads the population activity. Disparity is recovered by matching the population response to a set of canonical templates, derived from the mean response to white noise stimuli at a range of disparities. Model predictions are qualitatively consistent with a variety of psychophysi...
AbstractA new study has shown that neurons in the visual cortex are specialized to encode the larger...
To perceive the visual world as three-dimensional, the brain has to reconstruct spatial structure fr...
The visual perception of 3D depth is underpinned by the brain’s ability to combine signals from the ...
Although binocular neurons in the primary visual cortex are sensitive to retinal disparity, their ac...
AbstractAlthough binocular neurons in the primary visual cortex are sensitive to retinal disparity, ...
The visual cortex is able to extract disparity information through the use of binocular cells. This ...
The past decades of research in visual neuroscience have generated a large and disparate body of lit...
Depth information using the biological Disparity Energy Model can be obtained by using a population ...
A great challenge of systems neuroscience is to understand the computations that underlie perceptual...
The depth cue is a fundamental piece of information for artificial and living beings who interact wi...
Neurophysiological data support two models for the disparity selectivity of binocular simple and com...
In mammals, binocular fusion takes place over a limited region, known as Panum's fusional area, whic...
3D vision is a key process in the spatial understanding of the world. For decades, numerous research...
The relative depth of objects causes small shifts in the left and right retinal positions of these o...
The neural processing of binocular disparity is one of the main mechanisms allowing three-dimensiona...
AbstractA new study has shown that neurons in the visual cortex are specialized to encode the larger...
To perceive the visual world as three-dimensional, the brain has to reconstruct spatial structure fr...
The visual perception of 3D depth is underpinned by the brain’s ability to combine signals from the ...
Although binocular neurons in the primary visual cortex are sensitive to retinal disparity, their ac...
AbstractAlthough binocular neurons in the primary visual cortex are sensitive to retinal disparity, ...
The visual cortex is able to extract disparity information through the use of binocular cells. This ...
The past decades of research in visual neuroscience have generated a large and disparate body of lit...
Depth information using the biological Disparity Energy Model can be obtained by using a population ...
A great challenge of systems neuroscience is to understand the computations that underlie perceptual...
The depth cue is a fundamental piece of information for artificial and living beings who interact wi...
Neurophysiological data support two models for the disparity selectivity of binocular simple and com...
In mammals, binocular fusion takes place over a limited region, known as Panum's fusional area, whic...
3D vision is a key process in the spatial understanding of the world. For decades, numerous research...
The relative depth of objects causes small shifts in the left and right retinal positions of these o...
The neural processing of binocular disparity is one of the main mechanisms allowing three-dimensiona...
AbstractA new study has shown that neurons in the visual cortex are specialized to encode the larger...
To perceive the visual world as three-dimensional, the brain has to reconstruct spatial structure fr...
The visual perception of 3D depth is underpinned by the brain’s ability to combine signals from the ...