English

Tri-connectivity Augmentation in Trees

Combinatorics 2016-01-05 v1 Discrete Mathematics

Abstract

For a connected graph, a {\em minimum vertex separator} is a minimum set of vertices whose removal creates at least two connected components. The vertex connectivity of the graph refers to the size of the minimum vertex separator and a graph is kk-vertex connected if its vertex connectivity is kk, k1k\geq 1. Given a kk-vertex connected graph GG, the combinatorial problem {\em vertex connectivity augmentation} asks for a minimum number of edges whose augmentation to GG makes the resulting graph (k+1)(k+1)-vertex connected. In this paper, we initiate the study of rr-vertex connectivity augmentation whose objective is to find a (k+r)(k+r)-vertex connected graph by augmenting a minimum number of edges to a kk-vertex connected graph, r1r \geq 1. We shall investigate this question for the special case when GG is a tree and r=2r=2. In particular, we present a polynomial-time algorithm to find a minimum set of edges whose augmentation to a tree makes it 3-vertex connected. Using lower bound arguments, we show that any tri-vertex connectivity augmentation of trees requires at least 2l1+l22\lceil \frac {2l_1+l_2}{2} \rceil edges, where l1l_1 and l2l_2 denote the number of degree one vertices and degree two vertices, respectively. Further, we establish that our algorithm indeed augments this number, thus yielding an optimum algorithm.

Keywords

Cite

@article{arxiv.1601.00506,
  title  = {Tri-connectivity Augmentation in Trees},
  author = {S. Dhanalakshmi and N. Sadagopan and D. Sunil Kumar},
  journal= {arXiv preprint arXiv:1601.00506},
  year   = {2016}
}

Comments

10 pages, 2 figures, 3 algorithms, Presented in ICGTA 2015

R2 v1 2026-06-22T12:22:29.490Z