Towards Scalable Persistence-Based Topological Optimization
摘要
Persistence-based topological optimization deforms a point cloud by minimizing objectives of the form , where is a persistence diagram. In practice, optimization is limited by two coupled issues: persistent homology is typically computed on subsamples, and the resulting topological gradients are highly sparse, with only a few anchor points receiving nonzero updates. Motivated by diffeomorphic interpolation, which extends sparse gradients to smooth ambient vector fields via Reproducing Kernel Hilbert Space (RKHS) interpolation, we propose a more scalable pipeline that improves both subsampling and gradient extension. We introduce subsampling via random slicing, a lightweight scheme that promotes iteration-wise geometric coverage and mitigates density bias. We further replace the costly kernel solve with a fast Nadaraya-Watson (NW) Gaussian convolution, producing a globally defined smooth update field at a fraction of the computational cost, while being more suited for topological optimization tasks. We provide theoretical guarantees for NW smoothing, including anchor approximation bounds and global Lipschitz estimates. Experiments in D and D show that combining random slicing with NW smoothing yields consistent speedups and improved objective values over other baselines on common persistence losses.
引用
@article{arxiv.2605.10996,
title = {Towards Scalable Persistence-Based Topological Optimization},
author = {Abderrahim Bendahi and Alexandre Duplessis and Arnaud Fickinger},
journal= {arXiv preprint arXiv:2605.10996},
year = {2026}
}