Geodesics in Heat
Abstract
We introduce the heat method for computing the shortest geodesic distance to a specified subset (e.g., point or curve) of a given domain. The heat method is robust, efficient, and simple to implement since it is based on solving a pair of standard linear elliptic problems. The method represents a significant breakthrough in the practical computation of distance on a wide variety of geometric domains, since the resulting linear systems can be prefactored once and subsequently solved in near-linear time. In practice, distance can be updated via the heat method an order of magnitude faster than with state-of-the-art methods while maintaining a comparable level of accuracy. We provide numerical evidence that the method converges to the exact geodesic distance in the limit of refinement; we also explore smoothed approximations of distance suitable for applications where more regularity is required.
Cite
@article{arxiv.1204.6216,
title = {Geodesics in Heat},
author = {Keenan Crane and Clarisse Weischedel and Max Wardetzky},
journal= {arXiv preprint arXiv:1204.6216},
year = {2013}
}