Exponential Domination in Subcubic Graphs

Abstract

As a natural variant of domination in graphs, Dankelmann et al. [Domination with exponential decay, Discrete Math. 309 (2009) 5877-5883] introduce exponential domination, where vertices are considered to have some dominating power that decreases exponentially with the distance, and the dominated vertices have to accumulate a sufficient amount of this power emanating from the dominating vertices. More precisely, if S is a set of vertices of a graph G, then S is an exponential dominating set of G if Σv∈ S(12) dist(G,S)(u,v)-1≥ 1 for every vertex u in V(G) S, where dist(G,S)(u,v) is the distance between u∈ V(G) S and v∈ S in the graph G-(S \ v\). The exponential domination number γe(G) of G is the minimum order of an exponential dominating set of G. In the present paper we study exponential domination in subcubic graphs. Our results are as follows: If G is a connected subcubic graph of order n(G), then n(G)62(n(G)+2)+4≤ γe(G)≤ 13(n(G)+2). For every ε>0, there is some g such that γe(G)≤ ε n(G) for every cubic graph G of girth at least g. For every 0<α<23(2), there are infinitely many cubic graphs G with γe(G)≤ 3n(G)(n(G))α. If T is a subcubic tree, then γe(T)≥ 16(n(T)+2). For a given subcubic tree, γe(T) can be determined in polynomial time. The minimum exponential dominating set problem is APX-hard for subcubic graphs.