A Dividing Line for Structural Kernelization of Component Order Connectivity via Distance to Bounded Pathwidth

Abstract

In this work we study a classic generalization of the Vertex Cover (VC) problem, called the Component Order Connectivity (COC) problem. In COC, given an undirected graph G, integers d ≥ 1 and k, the goal is to determine if there is a set of at most k vertices whose deletion results in a graph where each connected component has at most d vertices. When d=1, this is exactly VC. This work is inspired by polynomial kernelization results with respect to structural parameters for VC. On one hand, Jansen & Bodlaender [TOCS 2013] show that VC admits a polynomial kernel when the parameter is the distance to treewidth-1 graphs, on the other hand Cygan, Lokshtanov, Pilipczuk, Pilipczuk & Saurabh [TOCS 2014] showed that VC does not admit a polynomial kernel when the parameter is distance to treewidth-2 graphs. Greilhuber & Sharma [IPEC 2024] showed that, for any d ≥ 2, d-COC cannot admit a polynomial kernel when the parameter is distance to a forest of pathwidth 2. Here, d-COC is the same as COC only that d is a fixed constant not part of the input. We complement this result and show that like for the VC problem where distance to treewidth-1 graphs versus distance to treewidth-2 graphs is the dividing line between structural parameterizations that allow and respectively disallow polynomial kernelization, for COC this dividing line happens between distance to pathwidth-1 graphs and distance to pathwidth-2 graphs. The main technical result of this work is that COC admits a polynomial kernel parameterized by distance to pathwidth-1 graphs plus d.

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