Title :
Fast partial search solution to the 3D SFM problem
Author_Institution :
Center for Autom. Res., Maryland Univ., College Park, MD, USA
Abstract :
In this paper, we present a robust and computationally efficient technique for estimating the focus of expansion (FOE) of an optical flow field, using fast partial search. For each candidate location on a discrete sampling of the image area, we generate a linear system of equations for determining the remaining unknowns, viz. rotation and inverse depth. We compute the least squares error of the system without actually solving the equations, to generate an error surface that describes the goodness of fit across the hypotheses. Using Fourier techniques, we prove that given an N×N flow field, the FOE can be estimated in O(N2logN) operations. Since the resulting system is linear, bounded performances in the data lead to bounded errors. In order to demonstrate its performance on real-world problems, we apply this technique for detecting obstacles in monocular navigation imagery
Keywords :
Fourier transforms; image sequences; least squares approximations; motion estimation; 3D SFM problem; Fourier techniques; bounded errors; bounded performances; computationally efficient technique; error surface; focus of expansion estimation; least squares error; monocular navigation imagery; obstacles detection; optical flow field; partial search solution; structure from motion; Equations; Focusing; Image generation; Image motion analysis; Image sampling; Least squares methods; Linear systems; Optical computing; Robustness; Surface fitting;
Conference_Titel :
Computer Vision, 1999. The Proceedings of the Seventh IEEE International Conference on
Conference_Location :
Kerkyra
Print_ISBN :
0-7695-0164-8
DOI :
10.1109/ICCV.1999.791268
