English

QPTAS for Geometric Set-Cover Problems via Optimal Separators

Computational Geometry 2014-04-08 v2

Abstract

Weighted geometric set-cover problems arise naturally in several geometric and non-geometric settings (e.g. the breakthrough of Bansal-Pruhs (FOCS 2010) reduces a wide class of machine scheduling problems to weighted geometric set-cover). More than two decades of research has succeeded in settling the (1+ϵ)(1+\epsilon)-approximability status for most geometric set-cover problems, except for four basic scenarios which are still lacking. One is that of weighted disks in the plane for which, after a series of papers, Varadarajan (STOC 2010) presented a clever \emph{quasi-sampling} technique, which together with improvements by Chan \etal~(SODA 2012), yielded a O(1)O(1)-approximation algorithm. Even for the unweighted case, a PTAS for a fundamental class of objects called pseudodisks (which includes disks, unit-height rectangles, translates of convex sets etc.) is currently unknown. Another fundamental case is weighted halfspaces in 3\Re^3, for which a PTAS is currently lacking. In this paper, we present a QPTAS for all of these remaining problems. Our results are based on the separator framework of Adamaszek-Wiese (FOCS 2013, SODA 2014), who recently obtained a QPTAS for weighted independent set of polygonal regions. This rules out the possibility that these problems are APX-hard, assuming NPDTIME(2polylog(n))\textbf{NP} \nsubseteq \textbf{DTIME}(2^{polylog(n)}). Together with the recent work of Chan-Grant (CGTA 2014), this settles the APX-hardness status for all natural geometric set-cover problems.

Keywords

Cite

@article{arxiv.1403.0835,
  title  = {QPTAS for Geometric Set-Cover Problems via Optimal Separators},
  author = {Nabil H. Mustafa and Rajiv Raman and Saurabh Ray},
  journal= {arXiv preprint arXiv:1403.0835},
  year   = {2014}
}

Comments

26 pages. Revised to include an additional set-cover QPTAS for halfspaces

R2 v1 2026-06-22T03:19:58.589Z