Stabbing line segments with disks: complexity and approximation algorithms

Abstract

Computational complexity and approximation algorithms are reported for a problem of stabbing a set of straight line segments with the least cardinality set of disks of fixed radii r>0 where the set of segments forms a straight line drawing G=(V,E) of a planar graph without edge crossings. Close geometric problems arise in network security applications. We give strong NP-hardness of the problem for edge sets of Delaunay triangulations, Gabriel graphs and other subgraphs (which are often used in network design) for r∈ [d,η d] and some constant η where d and d are Euclidean lengths of the longest and shortest graph edges respectively. Fast O(|E||E|)-time O(1)-approximation algorithm is proposed within the class of straight line drawings of planar graphs for which the inequality r≥ η d holds uniformly for some constant η>0, i.e. when lengths of edges of G are uniformly bounded from above by some linear function of r.