English

A new separation theorem with geometric applications

Computational Geometry 2015-04-21 v1

Abstract

Let G=(V(G),E(G))G=(V(G), E(G)) be an undirected graph with a measure function μ\mu assigning non-negative values to subgraphs HH so that μ(H)\mu(H) does not exceed the clique cover number of HH. When μ\mu satisfies some additional natural conditions, we study the problem of separating GG into two subgraphs, each with a measure of at most 2μ(G)/32\mu(G)/3 by removing a set of vertices that can be covered with a small number of cliques GG. When E(G)=E(G1)E(G2)E(G)=E(G_1)\cap E(G_2), where G1=(V(G1),E(G1))G_1=(V(G_1),E(G_1)) is a graph with V(G1)=V(G)V(G_1)=V(G), and G2=(V(G2),E(G2))G_2=(V(G_2), E(G_2)) is a chordal graph with V(G2)=V(G)V(G_2)=V(G), we prove that there is a separator SS that can be covered with O(lμ(G))O(\sqrt{l\mu(G)}) cliques in GG, where l=l(G,G1)l=l(G,G_1) is a parameter similar to the bandwidth, which arises from the linear orderings of cliques covers in G1G_1. The results and the methods are then used to obtain exact and approximate algorithms which significantly improve some of the past results for several well known NP-hard geometric problems. In addition, the methods involve introducing new concepts and hence may be of an independent interest.

Keywords

Cite

@article{arxiv.1504.04938,
  title  = {A new separation theorem with geometric applications},
  author = {Farhad Shahrokhi},
  journal= {arXiv preprint arXiv:1504.04938},
  year   = {2015}
}

Comments

Proceedings of EuroCG 2010, Dortmund, Germany, March 22-24, 2010

R2 v1 2026-06-22T09:18:46.418Z