Distance-k locating-dominating sets in graphs
Abstract
Let G be a graph with vertex set V, and let k be a positive integer. A set D ⊂eq V is a distance-k dominating set of G if, for each vertex u ∈ V-D, there exists a vertex w∈ D such that d(u,w) k, where d(u,w) is the minimum number of edges linking u and w in G. Let dk(x, y)=\d(x,y), k+1\. A set R⊂eq V is a distance-k resolving set of G if, for any pair of distinct x,y∈ V, there exists a vertex z∈ R such that dk(x,z) ≠ dk(y,z). The distance-k domination number γk(G) (distance-k dimension k(G), respectively) of G is the minimum cardinality of all distance-k dominating sets (distance-k resolving sets, respectively) of G. The distance-k location-domination number, γLk(G), of G is the minimum cardinality of all sets S⊂eq V such that S is both a distance-k dominating set and a distance-k resolving set of G. Note that γL1(G) is the well-known location-domination number introduced by Slater in 1988. For any connected graph G of order n 2, we obtain the following sharp bounds: (1) γk(G) k(G)+1; (2) 2γk(G)+k(G) n; (3) 1 \γk(G), k(G)\ γLk(G) \k(G)+1, n-1\. We characterize G for which γLk(G)∈\1, |V|-1\. We observe that k(G)γk(G) can be arbitrarily large. Moreover, for any tree T of order n 2, we show that γLk(T) n-ex(T), where ex(T) denotes the number of exterior major vertices of T, and we characterize trees T achieving equality. We also examine the effect of edge deletion on the distance-k location-domination number of graphs.
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