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FORCING ROMAN DOMINATION IN GRAPHS
September 11th, 2019, 6:20AM
A set S of vertices is a dominating set if every vertex in V \ S has a neighbour in S. A Roman dominating function (RDF) on a graph G = (V,E) is defined to be a function f : V → {0, 1, 2} satisfying the condition that every vertex u for which f(u) = 0 is adjacent to at least one vertex v for which f(v) = 2. A Roman dominating function f of G can also be represented by a set of ordered pairs Sf = {(v, f(v)) : v ∈ V } . A subset T of Sf is called a forcing subset of Sf if Sf is the unique extension of T to a γR(G)-function. We define a forcing Roman domination number of Sf denoted by F(Sf, γR), as F(Sf, R) = min{|T| : T is aforcing subset of Sf }. The forcing Roman domination number F(G, γR) of G is degined as F(G; γR) = min{f(Sf, γR) : f is a γR(G) function}. Hence for every graph G, F(G,γR) ≥ 0. In this paper, we initiate a study of this parameter. We also obtain the forcing Roman domination number of paths, cycles, complete graphs, and complete multipartite.
FORCING ROMAN DOMINATION IN GRAPHS
September 11th, 2019, 6:20AM
A set S of vertices is a dominating set if every vertex in V \ S has a neighbour in S. A Roman dominating function (RDF) on a graph G = (V,E) is defined to be a function f : V → {0, 1, 2} satisfying the condition that every vertex u for which f(u) = 0 is adjacent to at least one vertex v for which f(v) = 2. A Roman dominating function f of G can also be represented by a set of ordered pairs Sf = {(v, f(v)) : v ∈ V } . A subset T of Sf is called a forcing subset of Sf if Sf is the unique extension of T to a γR(G)-function. We define a forcing Roman domination number of Sf denoted by F(Sf, γR), as F(Sf, R) = min{|T| : T is aforcing subset of Sf }. The forcing Roman domination number F(G, γR) of G is degined as F(G; γR) = min{f(Sf, γR) : f is a γR(G) function}. Hence for every graph G, F(G,γR) ≥ 0. In this paper, we initiate a study of this parameter. We also obtain the forcing Roman domination number of paths, cycles, complete graphs, and complete multipartite.