Abstract
Our goal in this paper is the development of fast algorithms for recognizing general classes of graphs. We seek algorithms whose complexity can be expressed as a linear function of the graph size plus an exponential function of k, a natural parameter describing the class. Our classes are of the form \( \mathcal{W}_k (\mathcal{G}) \), graphs that can be formed by augmenting graphs in \( \mathcal{G} \) by adding at most k vertices (and incident edges). If \( \mathcal{G} \) is the class of edgeless graphs, \( \mathcal{W}_k (\mathcal{G}) \) is the class of graphs with a vertex cover of size at most k.
We describe a recognition algorithm for \( \mathcal{W}_k (\mathcal{G}) \) running in time O((g + k)|V(G)| + (fk) k), where g and f are modest constants depending on the class \( \mathcal{G} \), when \( \mathcal{G} \) is a minor-closed class such that each graph in G has bounded maximum degree, and all obstructions of G (minor-minimal graphs outside \( \mathcal{G} \)) are connected. If \( \mathcal{G} \) is the class of graphs with maximum degree bounded by D (not closed under minors), we can still recognize graphs in \( \mathcal{W}_k (\mathcal{G}) \) in time O(|V(G)|(D + k) + k(D + k) k+3).
Our results are obtained by considering minor-closed classes \( \mathcal{G} \) for which all obstructions are connected graphs, and showing that the size of any obstruction for \( \mathcal{W}_k (\mathcal{G}) \) is O(tk 7 + t 7 k 2), where t is a bound on the size of obstructions for \( \mathcal{G} \).
Research supported by the Natural Sciences and Engineering Research Council of Canada, Ministry of Education and Culture of Spain (grant number MEC-DGES SB98 0K148809), and EU project ALCOM-FT (IST-99-14186).
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Nishimura, N., Ragde, P., Thilikos, D.M. (2001). Fast Fixed-Parameter Tractable Algorithms for Nontrivial Generalizations of Vertex Cover. In: Dehne, F., Sack, JR., Tamassia, R. (eds) Algorithms and Data Structures. WADS 2001. Lecture Notes in Computer Science, vol 2125. Springer, Berlin, Heidelberg. https://doi.org/10.1007/3-540-44634-6_8
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