Connected vertex covers in dense graphs

• Published in: Theoretical computer science Vol. 411; no. 26-28; pp. 2581 - 2590
• Main Authors: CARDINAL, Jean, LEVY, Eythan
• Format: Journal Article
• Language: English
• Published: Oxford Elsevier 06.06.2010
• Subjects: Algorithmics. Computability. Computer arithmetics; Algorithms; Applied sciences; Approximation; C (programming language); Computer science; control theory; systems; Exact sciences and technology; Graphs; Information retrieval. Graph; Mathematical analysis; Miscellaneous; Theoretical computing; Upper bounds; Vertex; Approximation; Computer theory; Connected vertex cover; Average; Connected graph; Vertex(graph); Approximation algorithm; Upper bound; Dense graph; Graph connectivity; Graph degree; Subgraph; Vertex cover
• ISSN: 0304-3975; 1879-2294
• DOI: 10.1016/j.tcs.2010.03.021

We consider the variant of the minimum vertex cover problem in which we require that the cover induces a connected subgraph. We give new approximation results for this problem in dense graphs, in which either the minimum or the average degree is linear. In particular, we prove tight parameterized upper bounds on the approximation returned by Savage's algorithm, and extend a vertex cover algorithm from Karpinski and Zelikovsky to the connected case. The new algorithm approximates the minimum connected vertex cover problem within a factor strictly less than 2 on all dense graphs. All these results are shown to be tight. Finally, we introduce the price of connectivity for the vertex cover problem, defined as the worst-case ratio between the sizes of a minimum connected vertex cover and a minimum vertex cover. We prove that the price of connectivity is bounded by 2 / ( 1 + I mu ) in graphs with average degree I mu n , and give a family of near-tight examples.