Segmentation and Interpolation in Stereopsis and Motion
Anderson, Barton   
Massachusetts Institute of Technology, Cambridge, MA, United States

The proposed project involves psychophysical investigations of the mechanisms underlying the recovery of surface structure in stereopsis and motion perception. Virtually all of the work in stereopsis and motion in the past century has focused on the matching or correspondence problem. The tacit assumption has been that an understanding of matching is both necessary and sufficient for understanding the recovery of 3D structure from 2D images. The proposed work will pursue experiments into two forms of image segmentation that reveal the insufficiency of the view. Specifically, we propose experiments to evaluate how multiple views are segmented into distinct objects along occluding boundaries, and into distinct layers when computing surface lightness and/or opacity. The broad goal of the proposed project is to fill the current gap in our understanding of the mechanisms underlying how the human visual system uses multiple views of images to decompose 2 D images into a 3D representation of surfaces in depth.
The specific aims of the project are: 1) To explore the psychophysical properties that cause binocular and moving displays to be decomposed into matchable and unmatchable features, critical for understanding how surface boundaries are recovered in these domains. 2) To understand how image regions are decomposed into a multi-layered, 3D representation of surface lightness and transparency. 3) To develop a theoretical framework that integrates these two forms of image segmentation. The experiments entail a number of different methods that are tailored to the specific question under study. In general, two types of methods will be used. One method will measure perceptual sensitivity by requiring observers to discriminate (typically two) displays. Sensitivity to the property on interest (such as surface boundaries) is captured in an observer's ability to perform the discrimination. A second method requires observers to manipulate a graphics display to match the perceptual quality of interest (such as depth, orientation, or three-dimensional shape of a pattern). These measurements will be analyzed to determine how surface boundaries are recovered and surface properties such as lightness and transparency is attributed to moving and/or stereoscopic displays.