We propose a novel variational approach for computing neural Signed Distance Fields (SDF) from unoriented point clouds. To this end, we replace the commonly used eikonal equation with the heat method, carrying over to the neural domain what has long been standard practice for computing distances on discrete surfaces. This yields two convex optimization problems for whose solution we employ neural networks: We first compute a neural approximation of the gradients of the unsigned distance field through a small time step of heat flow with weighted point cloud densities as initial data. Then we use it to compute a neural approximation of the SDF. We prove that the underlying variational problems are well-posed. Through numerical experiments, we demonstrate that our method provides state-of-the-art surface reconstruction and consistent SDF gradients. Furthermore, we show in a proof-of-concept that it is accurate enough for solving a PDE on the zero-level set.
View on arXiv@article{weidemaier2025_2504.11212,
title={ SDFs from Unoriented Point Clouds using Neural Variational Heat Distances },
author={ Samuel Weidemaier and Florine Hartwig and Josua Sassen and Sergio Conti and Mirela Ben-Chen and Martin Rumpf },
journal={arXiv preprint arXiv:2504.11212},
year={ 2025 }
}