A Note on Roman \2\-domination problem in graphs

Abstract

For a graph G=(V,E), a Roman \2\-dominating function (R2DF)f:V→ \0,1,2\ has the property that for every vertex v∈ V with f(v)=0, either there exists a neighbor u∈ N(v), with f(u)=2, or at least two neighbors x,y∈ N(v) having f(x)=f(y)=1. The weight of a R2DF is the sum f(V)=Σv∈ Vf(v), and the minimum weight of a R2DF is the Roman \2\-domination number γ\R2\(G). A R2DF is independent if the set of vertices having positive function values is an independent set. The independent Roman \2\-domination number i\R2\(G) is the minimum weight of an independent Roman \2\-dominating function on G. In this paper, we show that the decision problem associated with γ\R2\(G) is NP-complete even when restricted to split graphs. We design a linear time algorithm for computing the value of i\R2\(T) for any tree T. This answers an open problem raised by Rahmouni and Chellali [Independent Roman \2\-domination in graphs, Discrete Applied Mathematics 236 (2018), 408-414]. Chellali, Haynes, Hedetniemi and McRae chellali2016roman have showed that Roman \2\-domination number can be computed for the class of trees in linear time. As a generalization, we present a linear time algorithm for solving the Roman \2\-domination problem in block graphs.