Abstract
Visual perception is probably a simultaneous local and global process. Local signals define the global picture, and the global percept defines which local features are the signal and which ones are noise. This mode of operation pertains to many aspects of vision, and particularly to stereoscopic vision. The global 3D percept derived from a random dot stereogram (RDS) display is assebmbled from local patches. In this article, we claim that the local patches on which stereoscopic visual perception depend, could in fact be identified as the hypercolumns of the visual cortex.
Stereoscopic vision is extremely precise in detecting minute differences between adjacent depth planes, but quite imprecise in estimating absolute depth. In this paper, we address the issue of the spatial acuity (and not the stereo acuity) of stereopsis. Static RDS (random dot stereograms) stimuli were used to find the spatial grain in which human stereoscopic vision operates. Using psychophysical experiments it was found that foveally, stimuli smaller than 8’ cannot be accurately perceived. For other eccentricities, it was found that this threshold is inversely proportional to the Cortical Magnification factor. We interpret this spatial size limit, which is an order of magnitude larger than visual spatial acuity, as an indication that stereopsis is an area based comparison rather than a point process, and discuss the relations between the cortical “patch” size that corresponds to this 8’ limit and Ocular Dominance Columns.
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Schlesinger, B.Y., Yeshurun, Y. (2002). Spatial Size Limits in Stereoscopic Vision. In: Cantoni, V., Marinaro, M., Petrosino, A. (eds) Visual Attention Mechanisms. Springer, Boston, MA. https://doi.org/10.1007/978-1-4615-0111-4_16
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DOI: https://doi.org/10.1007/978-1-4615-0111-4_16
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