Early neural mechanisms for the measurement of binocular disparity appear to operate in a manner consistent with cross-correlation-like processes. Consequently, cross-correlation, or cross-correlation-like procedures have been used in a range of models of disparity measurement. Using such procedures as the basis for disparity measurement creates a preference for correspondence solutions that maximize the similarity between local left and right eye image regions. Here, we examine how observers’ perception of depth in an ambiguous stereogram is affected by manipulations of luminance and orientation-based image similarity. Results show a strong effect of coarse-scale luminance similarity manipulations, but a relatively weak effect of fin...
Purpose: Perceiving binocular depth relies on the ability of our visual system to precisely match co...
Stereo matching, i.e., the matching by the visual system of corresponding parts of the images seen b...
AbstractOur ability to see the world in depth is a major accomplishment of the brain. Previous model...
Early neural mechanisms for the measurement of binocular disparity appear to operate in a manner con...
AbstractPrevious work [Prince, S. J. D, & Eagle, R. A. (1999). Size-disparity correlation in human b...
AbstractPrevious data [Prince, S.J.D., & Eagle, R.A., (1999). Size-disparity correlation in human bi...
Perception of stereoscopic depth requires that visual systems solve a correspondence problem: find p...
Perception of stereoscopic depth requires that visual systems solve a correspondence problem: find p...
AbstractStereoscopic vision is achieved by matching images in the two eyes. It is well known that th...
The binocular energy model of neural responses predicts that depth from binocular disparity might be...
AbstractIn spite of numerous studies in stereoscopic perception, it is still not clear how the visua...
Visual images from the two eyes are transmitted to the brain. Because the eyes are horizontally sepa...
To compute depth from binocular disparity, the visual system must correctly link corresponding point...
The first stage of processing of binocular information in the visual cortex is performed by mechanis...
A pioneering study by J. M. Harris and A. J. Parker (1995) found that disparity judgments using rand...
Purpose: Perceiving binocular depth relies on the ability of our visual system to precisely match co...
Stereo matching, i.e., the matching by the visual system of corresponding parts of the images seen b...
AbstractOur ability to see the world in depth is a major accomplishment of the brain. Previous model...
Early neural mechanisms for the measurement of binocular disparity appear to operate in a manner con...
AbstractPrevious work [Prince, S. J. D, & Eagle, R. A. (1999). Size-disparity correlation in human b...
AbstractPrevious data [Prince, S.J.D., & Eagle, R.A., (1999). Size-disparity correlation in human bi...
Perception of stereoscopic depth requires that visual systems solve a correspondence problem: find p...
Perception of stereoscopic depth requires that visual systems solve a correspondence problem: find p...
AbstractStereoscopic vision is achieved by matching images in the two eyes. It is well known that th...
The binocular energy model of neural responses predicts that depth from binocular disparity might be...
AbstractIn spite of numerous studies in stereoscopic perception, it is still not clear how the visua...
Visual images from the two eyes are transmitted to the brain. Because the eyes are horizontally sepa...
To compute depth from binocular disparity, the visual system must correctly link corresponding point...
The first stage of processing of binocular information in the visual cortex is performed by mechanis...
A pioneering study by J. M. Harris and A. J. Parker (1995) found that disparity judgments using rand...
Purpose: Perceiving binocular depth relies on the ability of our visual system to precisely match co...
Stereo matching, i.e., the matching by the visual system of corresponding parts of the images seen b...
AbstractOur ability to see the world in depth is a major accomplishment of the brain. Previous model...