Abstract
The main result in this paper is a new lower bound to the eternal vertex cover number (evc number) of an arbitrary graph G in terms of the size of the smallest vertex cover in G that includes all the cut vertices of G. As a consequence, we obtain a quadratic complexity algorithm for finding the evc number of any chordal graph. Another consequence is a polynomial time approximation scheme for finding the evc number of internally triangulated planar graphs, for which exact determination of evc number is known to be NP-hard (Babu et al. in Discrete Appl Math, 2021. https://doi.org/10.1016/j.dam.2021.02.004). The lower bound is proven by considering a decomposition of the graph into a collection of edge disjoint induced subgraphs, and deriving a lower bound for the evc number of the whole graph in terms of bounds obtained for the subgraphs. As another consequence of the bounding technique, we obtain a construction of a family of biconnected bipartite graphs such that for any \(\epsilon >0\), there exists a graph in the family such that the ratio of its evc number to the size of its minimum vertex cover exceeds \(2-\epsilon \). This construction is asymptotically optimal, as it is known (Klostermeyer and Mynhardt in Aust J Comb 45:235–250, 2009) that this ratio has to be strictly less than 2 for biconnected graphs.
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Acknowledgements
The initial results presented in this paper appeared in: Jasine Babu, Veena Prabhakaran (2020) A new lower bound for the eternal vertex cover number of graphs. COCOON 2020: 27-39.
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Babu, J., Prabhakaran, V. A new lower bound for the eternal vertex cover number of graphs. J Comb Optim 44, 2482–2498 (2022). https://doi.org/10.1007/s10878-021-00764-8
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DOI: https://doi.org/10.1007/s10878-021-00764-8