A Primal-Dual Level Set Method for Computing Geodesic Distances
Abstract
The numerical computation of shortest paths or geodesics on surfaces, along with the associated geodesic distance, has a wide range of applications. Compared to Euclidean distance computation, these tasks are more complex due to the influence of surface geometry on the behavior of shortest paths. This paper introduces a primal-dual level set method for computing geodesic distances. A key insight is that the underlying surface can be implicitly represented as a zero level set, allowing us to formulate a constraint minimization problem. We employ the primal-dual methodology, along with regularization and acceleration techniques, to develop our algorithm. This approach is robust, efficient, and easy to implement. We establish a convergence result for the high-resolution PDE system, and numerical evidence suggests that the method converges to a geodesic in the limit of refinement.
Cite
@article{arxiv.2601.23244,
title = {A Primal-Dual Level Set Method for Computing Geodesic Distances},
author = {Hailiang Liu and Laura Zinnel},
journal= {arXiv preprint arXiv:2601.23244},
year = {2026}
}
Comments
27 pages, 10 figures