3D Reconstruction,
Perception, and Recognition of Reflective Objects
Professor Silvio Savarese
University of Michigan
Department of Electrical
Engineering
and Computer Science
Abstract:
The
ability to perceive and interpret the geometric shape and semantic meaning of
materials and objects is essential for an intelligent visual system. A
number of extensively studied cues, notably stereoscopic disparity, texture
gradient, motion parallax, contours and shading, have been shown to carry
valuable information on object surface shape. Unfortunately, many objects of
interest and most man-made surfaces, such as a silver plate, an industrial
structure or a clean automobile, are smooth and shiny, violating the hypotheses
that underlie the analysis of those cues. For specular objects, however, one
important but traditionally overlooked cue is the reflection of the
environment: a deformed picture of the surrounding scene can be seen on the
surface of the specular object— the degree and type of deformation depend
upon its shape.
In
this talk I introduce a geometrical and algebraic characterization of how a
patch of the scene is mapped into an image by a mirror surface of given shape.
I will then develop solutions to the inverse problem of deriving surface shape
from mirror reflections in a single image and demonstrate that local
information about the geometry of the surface can be fully estimated up to
third order. Our theoretical results are validated by both numerical
simulations and experiments with real surfaces. I will also give some insights
into my research on human perception of shape from reflections through
psychophysics experiments. Our goal is to provide a benchmark, as well as
inspire possible technical approaches, for computational work. We find that, surprisingly,
humans are very poor at judging the shape of mirror surfaces when additional
visual cues (i.e., contour, shading, stereo, texture) are not visible. Finally,
I will briefly describe my recent work on recognizing specular materials by
using the information from distorted scenes.
Friday, October 3, 2008
3:30 – 4:30 p.m.
Rm. 1500 EECS