Abstract
When one views a square-wave grating and dichoptically changes the average luminance or contrast of the monocular images, at least three perceptual phenomena might occur. These are the Venetian blind effect, or a perceived rotation of the bars around individual vertical axes; binocular luster, or a perceived shimmering; and binocular rivalry, or an alternating perception between the views of the two eyes. Perception of luster and rivalry occur when the "light bars" in the grating dichoptically straddle the background luminance (one eye’s image has a higher luminance than the background and the other eye’s image has a lower luminance than the background), with little impact from the "dark bars." Perception of rotation, on the other hand, is related to average luminance or contrast disparity, independent of whether or not the "light bars" straddle the background luminance. The patterns for perceived rotation versus binocular luster and binocular rivalry suggest at least two separate mechanisms in the visual system for processing luminance and contrast information over and above their differing physiological states suggested by their different appearances. While luster and rivalry depend directly on the relation between stimuli and the background, perceived rotation depends on the magnitude of the luminance or contrast disparity, as described by the generalized difference model.
Highlights
Binocular vision allows us to detect differences between the two eyes’ views, extracting information from binocular disparities
We demonstrate that the Venetian blind effect, binocular luster, and binocular rivalry can be perceived in the same square-wave grating by manipulating luminance or contrast disparity
The "average luminance" and "light luminance bars" plots can be compared to the plots for images with dichoptic luminance modulation, the "light contrast bars" plots can be compared to the plots for images with dichoptic contrast modulation, and the "dark bars" plots can be compared to both luminance and contrast modulations
Summary
Binocular vision allows us to detect differences between the two eyes’ views, extracting information from binocular disparities. (We use terminology from Macknik and Martinez-Conde [1]. Binocular image and monocular image refer to an image pair presented to two eyes or an image presented to one eye, respectively. Dichoptic image refers to a binocular image that has a disparity or disparities between its two monocular images. Monoptic image refers to an image that has no disparity. A term from general usage, refers to a participant’s unified perception of the presentation.) Geometric disparities are perhaps the best understood.
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