ProHD: Projection-Based Hausdorff Distance Approximation
Abstract
The Hausdorff distance (HD) is a robust measure of set dissimilarity, but computing it exactly on large, high-dimensional datasets is prohibitively expensive. We propose \textbf{ProHD}, a projection-guided approximation algorithm that dramatically accelerates HD computation while maintaining high accuracy. ProHD identifies a small subset of candidate "extreme" points by projecting the data onto a few informative directions (such as the centroid axis and top principal components) and computing the HD on this subset. This approach guarantees an underestimate of the true HD with a bounded additive error and typically achieves results within a few percent of the exact value. In extensive experiments on image, physics, and synthetic datasets (up to two million points in ), ProHD runs 10--100 faster than exact algorithms while attaining 5--20 lower error than random sampling-based approximations. Our method enables practical HD calculations in scenarios like large vector databases and streaming data, where quick and reliable set distance estimation is needed.
Cite
@article{arxiv.2511.18207,
title = {ProHD: Projection-Based Hausdorff Distance Approximation},
author = {Jiuzhou Fu and Luanzheng Guo and Nathan R. Tallent and Dongfang Zhao},
journal= {arXiv preprint arXiv:2511.18207},
year = {2025}
}