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Note on the hardness of generalized connectivity

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Abstract

Let G be a nontrivial connected graph of order n and let k be an integer with 2≤kn. For a set S of k vertices of G, let κ(S) denote the maximum number of edge-disjoint trees T 1,T 2,…,T in G such that V(T i )∩V(T j )=S for every pair i,j of distinct integers with 1≤i,j. Chartrand et al. generalized the concept of connectivity as follows: The k-connectivity, denoted by κ k (G), of G is defined by κ k (G)=min{κ(S)}, where the minimum is taken over all k-subsets S of V(G). Thus κ 2(G)=κ(G), where κ(G) is the connectivity of G, for which there are polynomial-time algorithms to solve it.

This paper mainly focus on the complexity of determining the generalized connectivity of a graph. At first, we obtain that for two fixed positive integers k 1 and k 2, given a graph G and a k 1-subset S of V(G), the problem of deciding whether G contains k 2 internally disjoint trees connecting S can be solved by a polynomial-time algorithm. Then, we show that when k 1 is a fixed integer of at least 4, but k 2 is not a fixed integer, the problem turns out to be NP-complete. On the other hand, when k 2 is a fixed integer of at least 2, but k 1 is not a fixed integer, we show that the problem also becomes NP-complete.

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Authors and Affiliations

  1. Center for Combinatorics and LPMC-TJKLC, Nankai University, Tianjin, 300071, China

    Shasha Li & Xueliang Li

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  1. Shasha Li
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  2. Xueliang Li
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Correspondence to Shasha Li.

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Li, S., Li, X. Note on the hardness of generalized connectivity. J Comb Optim 24, 389–396 (2012). https://doi.org/10.1007/s10878-011-9399-x

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  • DOI: https://doi.org/10.1007/s10878-011-9399-x

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