On k-vertex-edge domination of graph
Abstract
Let G=(V,E) be a simple undirected graph. The open neighbourhood of a vertex v in G is defined as NG(v)=\u∈ V~|~ uv∈ E\; whereas the closed neighbourhood is defined as NG[v]= NG(v) \v\. For an integer k, a subset D⊂eq V is called a k-vertex-edge dominating set of G if for every edge uv∈ E, |(NG[u] NG[v]) D|≥ k. In k-vertex-edge domination problem, our goal is to find a k-vertex-edge dominating set of minimum cardinality of an input graph G. In this paper, we first prove that the decision version of k-vertex-edge domination problem is NP-complete for chordal graphs. On the positive side, we design a linear time algorithm for finding a minimum k-vertex-edge dominating set of tree. We also prove that there is a O(((G)))-approximation algorithm for this problem in general graph G, where (G) is the maximum degree of G. Then we show that for a graph G with n vertices, this problem cannot be approximated within a factor of (1-ε) n for any ε >0 unless NP⊂eq DTIME(|V|O(|V|)). Finally, we prove that it is APX-complete for graphs with bounded degree k+3.
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