English

Hardness results on generalized connectivity

Combinatorics 2010-05-05 v1 Discrete Mathematics

Abstract

Let GG be a nontrivial connected graph of order nn and let kk be an integer with 2kn2\leq k\leq n. For a set SS of kk vertices of GG, let κ(S)\kappa (S) denote the maximum number \ell of edge-disjoint trees T1,T2,...,TT_1,T_2,...,T_\ell in GG such that V(Ti)V(Tj)=SV(T_i)\cap V(T_j)=S for every pair i,ji,j of distinct integers with 1i,j1\leq i,j\leq \ell. A collection {T1,T2,...,T}\{T_1,T_2,...,T_\ell\} of trees in GG with this property is called an internally disjoint set of trees connecting SS. Chartrand et al. generalized the concept of connectivity as follows: The kk-connectivityconnectivity, denoted by κk(G)\kappa_k(G), of GG is defined by κk(G)=\kappa_k(G)=min{κ(S)}\{\kappa(S)\}, where the minimum is taken over all kk-subsets SS of V(G)V(G). Thus κ2(G)=κ(G)\kappa_2(G)=\kappa(G), where κ(G)\kappa(G) is the connectivity of GG, for which there are polynomial-time algorithms to solve it. This paper mainly focus on the complexity of the generalized connectivity. At first, we obtain that for two fixed positive integers k1k_1 and k2k_2, given a graph GG and a k1k_1-subset SS of V(G)V(G), the problem of deciding whether GG contains k2k_2 internally disjoint trees connecting SS can be solved by a polynomial-time algorithm. Then, we show that when k1k_1 is a fixed integer of at least 4, but k2k_2 is not a fixed integer, the problem turns out to be NP-complete. On the other hand, when k2k_2 is a fixed integer of at least 2, but k1k_1 is not a fixed integer, we show that the problem also becomes NP-complete. Finally we give some open problems.

Keywords

Cite

@article{arxiv.1005.0488,
  title  = {Hardness results on generalized connectivity},
  author = {Shasha Li and Xueliang Li},
  journal= {arXiv preprint arXiv:1005.0488},
  year   = {2010}
}

Comments

10 pages

R2 v1 2026-06-21T15:18:16.794Z