English

Network Design Problems with Bounded Distances via Shallow-Light Steiner Trees

Data Structures and Algorithms 2014-09-24 v1

Abstract

In a directed graph GG with non-correlated edge lengths and costs, the \emph{network design problem with bounded distances} asks for a cost-minimal spanning subgraph subject to a length bound for all node pairs. We give a bi-criteria (2+ε,O(n0.5+ε))(2+\varepsilon,O(n^{0.5+\varepsilon}))-approximation for this problem. This improves on the currently best known linear approximation bound, at the cost of violating the distance bound by a factor of at most~2+ε2+\varepsilon. In the course of proving this result, the related problem of \emph{directed shallow-light Steiner trees} arises as a subproblem. In the context of directed graphs, approximations to this problem have been elusive. We present the first non-trivial result by proposing a (1+ε,O(Rε))(1+\varepsilon,O(|R|^{\varepsilon}))-ap\-proxi\-ma\-tion, where RR are the terminals. Finally, we show how to apply our results to obtain an (α+ε,O(n0.5+ε))(\alpha+\varepsilon,O(n^{0.5+\varepsilon}))-approximation for \emph{light-weight directed α\alpha-spanners}. For this, no non-trivial approximation algorithm has been known before. All running times depends on nn and ε\varepsilon and are polynomial in nn for any fixed ε>0\varepsilon>0.

Keywords

Cite

@article{arxiv.1409.6551,
  title  = {Network Design Problems with Bounded Distances via Shallow-Light Steiner Trees},
  author = {Markus Chimani and Joachim Spoerhase},
  journal= {arXiv preprint arXiv:1409.6551},
  year   = {2014}
}
R2 v1 2026-06-22T06:03:31.527Z