English

High-dimensional approximate $r$-nets

Computational Geometry 2017-05-09 v2

Abstract

The construction of rr-nets offers a powerful tool in computational and metric geometry. We focus on high-dimensional spaces and present a new randomized algorithm which efficiently computes approximate rr-nets with respect to Euclidean distance. For any fixed ϵ>0\epsilon>0, the approximation factor is 1+ϵ1+\epsilon and the complexity is polynomial in the dimension and subquadratic in the number of points. The algorithm succeeds with high probability. More specifically, the best previously known LSH-based construction of Eppstein et al.\ \cite{EHS15} is improved in terms of complexity by reducing the dependence on ϵ\epsilon, provided that ϵ\epsilon is sufficiently small. Our method does not require LSH but, instead, follows Valiant's \cite{Val15} approach in designing a sequence of reductions of our problem to other problems in different spaces, under Euclidean distance or inner product, for which rr-nets are computed efficiently and the error can be controlled. Our result immediately implies efficient solutions to a number of geometric problems in high dimension, such as finding the (1+ϵ)(1+\epsilon)-approximate kkth nearest neighbor distance in time subquadratic in the size of the input.

Keywords

Cite

@article{arxiv.1607.04755,
  title  = {High-dimensional approximate $r$-nets},
  author = {Georgia Avarikioti and Ioannis Z. Emiris and Loukas Kavouras and Ioannis Psarros},
  journal= {arXiv preprint arXiv:1607.04755},
  year   = {2017}
}

Comments

20 pages

R2 v1 2026-06-22T14:56:23.841Z