Linear kernels for edge deletion problems to immersion-closed graph classes
Abstract
Suppose is a finite family of graphs. We consider the following meta-problem, called -Immersion Deletion: given a graph and integer , decide whether the deletion of at most edges of can result in a graph that does not contain any graph from as an immersion. This problem is a close relative of the -Minor Deletion problem studied by Fomin et al. [FOCS 2012], where one deletes vertices in order to remove all minor models of graphs from . We prove that whenever all graphs from are connected and at least one graph of is planar and subcubic, then the -Immersion Deletion problem admits: a constant-factor approximation algorithm running in time ; a linear kernel that can be computed in time ; and a -time fixed-parameter algorithm, where count the vertices and edges of the input graph. These results mirror the findings of Fomin et al. [FOCS 2012], who obtained a similar set of algorithmic results for -Minor Deletion, under the assumption that at least one graph from is planar. An important difference is that we are able to obtain a linear kernel for -Immersion Deletion, while the exponent of the kernel of Fomin et al. for -Minor Deletion depends heavily on the family . In fact, this dependence is unavoidable under plausible complexity assumptions, as proven by Giannopoulou et al. [ICALP 2015]. This reveals that the kernelization complexity of -Immersion Deletion is quite different than that of -Minor Deletion.
Cite
@article{arxiv.1609.07780,
title = {Linear kernels for edge deletion problems to immersion-closed graph classes},
author = {Archontia C. Giannopoulou and Michał Pilipczuk and Dimitrios M. Thilikos and Jean-Florent Raymond and Marcin Wrochna},
journal= {arXiv preprint arXiv:1609.07780},
year = {2016}
}
Comments
44 pages