English

Net and Prune: A Linear Time Algorithm for Euclidean Distance Problems

Computational Geometry 2026-03-04 v3

Abstract

We provide a general framework for getting expected linear time constant factor approximations (and in many cases FPTASs) to several well-known problems in Computational Geometry, such as kk-center clustering and farthest nearest neighbor. The new approach is robust to variations in the input problem, and yet it is simple, elegant, and practical. In particular, many of these well-studied problems, which fit easily into our framework, either previously had no linear time approximation algorithm, or required rather involved algorithms and analysis. A short list of the problems we consider includes farthest nearest neighbor, kk-center clustering, smallest disk enclosing kk points, Hausdorff distance, kkth largest distance, kkth smallest mm-nearest neighbor distance, kkth heaviest edge in the MST, and other spanning-forest type problems, problems involving upward closed set systems, and more. Finally, we show how to extend our framework such that the linear running time bound holds with high probability.

Keywords

Cite

@article{arxiv.1409.7425,
  title  = {Net and Prune: A Linear Time Algorithm for Euclidean Distance Problems},
  author = {Sariel Har-Peled and Banjamin Raichel},
  journal= {arXiv preprint arXiv:1409.7425},
  year   = {2026}
}
R2 v1 2026-06-22T06:06:13.882Z