On \k\-Roman graphs: complexity of recognition and the case of split graphs
Abstract
For a positive integer k, a \k\-Roman dominating function of a graph G = (V,E) is a function f V → \0,1,…,k\ satisfying f (N(v)) ≥ k for each vertex v∈ V with f (v) = 0. Every graph G satisfies γ\Rk\(G) ≤ kγ(G), where γ\Rk\(G) denotes the minimum weight of a \k\-Roman dominating function of G and γ(G) is the domination number of G. In this work we study graphs for which the equality is reached, called \k\-Roman graphs. This extends the concept of \k\-Roman trees studied by Wang et al. in 2021 to general graphs. We prove that for every k≥ 3, the problem of recognizing \k\-Roman graphs is NP-hard, even when restricted to split graphs. We provide partial answers to the question of which split graphs are \2\-Roman: we characterize \2\-Roman split graphs that can be decomposed with respect to the split join operation into two smaller split graphs and classify the \k\-Roman property within two specific families of split graphs that are prime with respect to the split join operation: suns and their complements.
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