Decomposing Global Light Transport using Time of Flight Imaging - Robotics Institute Carnegie Mellon University

Decomposing Global Light Transport using Time of Flight Imaging

Di Wu, Matthew O'Toole, Andreas Velten, Amit Agrawal, and Ramesh Raskar
Conference Paper, Proceedings of (CVPR) Computer Vision and Pattern Recognition, pp. 366 - 373, June, 2012

Abstract

Global light transport is composed of direct and indirect components. In this paper, we take the first steps toward analyzing light transport using high temporal resolution information via time of flight (ToF) images. The time profile at each pixel encodes complex interactions between the incident light and the scene geometry with spatially-varying material properties. We exploit the time profile to decompose light transport into its constituent direct, subsurface scattering, and interreflection components. We show that the time profile is well modelled using a Gaussian function for the direct and interreflection components, and a decaying exponential function for the subsurface scattering component. We use our direct, subsurface scattering, and interreflection separation algorithm for four computer vision applications: recovering projective depth maps, identifying subsurface scattering objects, measuring parameters of analytical subsurface scattering models, and performing edge detection using ToF images.

BibTeX

@conference{Wu-2012-127030,
author = {Di Wu and Matthew O'Toole and Andreas Velten and Amit Agrawal and Ramesh Raskar},
title = {Decomposing Global Light Transport using Time of Flight Imaging},
booktitle = {Proceedings of (CVPR) Computer Vision and Pattern Recognition},
year = {2012},
month = {June},
pages = {366 - 373},
}