Algorithmic aspects of disjunctive domination in graphs

Abstract

For a graph G=(V,E), a set D⊂eq V is called a disjunctive dominating set of G if for every vertex v∈ V D, v is either adjacent to a vertex of D or has at least two vertices in D at distance 2 from it. The cardinality of a minimum disjunctive dominating set of G is called the disjunctive domination number of graph G, and is denoted by γ2d(G). The Minimum Disjunctive Domination Problem (MDDP) is to find a disjunctive dominating set of cardinality γ2d(G). Given a positive integer k and a graph G, the Disjunctive Domination Decision Problem (DDDP) is to decide whether G has a disjunctive dominating set of cardinality at most k. In this article, we first propose a linear time algorithm for MDDP in proper interval graphs. Next we tighten the NP-completeness of DDDP by showing that it remains NP-complete even in chordal graphs. We also propose a ((2++2)+1)-approximation algorithm for MDDP in general graphs and prove that MDDP can not be approximated within (1-ε) (|V|) for any ε>0 unless NP ⊂eq DTIME(|V|O( |V|)). Finally, we show that MDDP is APX-complete for bipartite graphs with maximum degree 3.