English

Spherical Discrepancy Minimization and Algorithmic Lower Bounds for Covering the Sphere

Computational Complexity 2019-11-19 v2

Abstract

Inspired by the boolean discrepancy problem, we study the following optimization problem which we term \textsc{Spherical Discrepancy}: given mm unit vectors v1,,vmv_1, \dots, v_m, find another unit vector xx that minimizes maxix,vi\max_i \langle x, v_i\rangle. We show that \textsc{Spherical Discrepancy} is APX-hard and develop a multiplicative weights-based algorithm that achieves optimal worst-case error bounds up to lower order terms. We use our algorithm to give the first non-trivial lower bounds for the problem of covering a hypersphere by hyperspherical caps of uniform volume at least 2o(n)2^{-o(\sqrt{n})}. We accomplish this by proving a related covering bound in Gaussian space and showing that in this \textit{large cap regime} the bound transfers to spherical space. Up to a log factor, our lower bounds match known upper bounds in the large cap regime.

Keywords

Cite

@article{arxiv.1907.05515,
  title  = {Spherical Discrepancy Minimization and Algorithmic Lower Bounds for Covering the Sphere},
  author = {Chris Jones and Matt McPartlon},
  journal= {arXiv preprint arXiv:1907.05515},
  year   = {2019}
}
R2 v1 2026-06-23T10:19:08.035Z