Weighted Efficient Domination for (P5+kP2)-Free Graphs in Polynomial Time

Abstract

Let G be a finite undirected graph. A vertex dominates itself and all its neighbors in G. A vertex set D is an efficient dominating set (e.d.\ for short) of G if every vertex of G is dominated by exactly one vertex of D. The Efficient Domination (ED) problem, which asks for the existence of an e.d.\ in G, is known to be -complete even for very restricted graph classes such as for claw-free graphs, for chordal graphs and for 2P3-free graphs (and thus, for P7-free graphs). We call a graph F a linear forest if F is cycle- and claw-free, i.e., its components are paths. Thus, the ED problem remains -complete for F-free graphs, whenever F is not a linear forest. Let WED denote the vertex-weighted version of the ED problem asking for an e.d. of minimum weight if one exists. In this paper, we show that WED is solvable in polynomial time for (P5+kP2)-free graphs for every fixed k, which solves an open problem, and, using modular decomposition, we improve known time bounds for WED on (P4+P2)-free graphs, (P6,S1,2,2)-free graphs, and on (2P3,S1,2,2)-free graphs and simplify proofs. For F-free graphs, the only remaining open case is WED on P6-free graphs.