English

Lower bounds on Locality Sensitive Hashing

Computational Geometry 2007-05-23 v2

Abstract

Given a metric space (X,dX)(X,d_X), c1c\ge 1, r>0r>0, and p,q[0,1]p,q\in [0,1], a distribution over mappings \h:XN\h:X\to \mathbb N is called a (r,cr,p,q)(r,cr,p,q)-sensitive hash family if any two points in XX at distance at most rr are mapped by \h\h to the same value with probability at least pp, and any two points at distance greater than crcr are mapped by \h\h to the same value with probability at most qq. This notion was introduced by Indyk and Motwani in 1998 as the basis for an efficient approximate nearest neighbor search algorithm, and has since been used extensively for this purpose. The performance of these algorithms is governed by the parameter ρ=log(1/p)log(1/q)\rho=\frac{\log(1/p)}{\log(1/q)}, and constructing hash families with small ρ\rho automatically yields improved nearest neighbor algorithms. Here we show that for X=1X=\ell_1 it is impossible to achieve ρ12c\rho\le \frac{1}{2c}. This almost matches the construction of Indyk and Motwani which achieves ρ1c\rho\le \frac{1}{c}.

Cite

@article{arxiv.cs/0510088,
  title  = {Lower bounds on Locality Sensitive Hashing},
  author = {Rajeev Motwani and Assaf Naor and Rina Panigrahy},
  journal= {arXiv preprint arXiv:cs/0510088},
  year   = {2007}
}