On the Parameterized Complexity of Reconfiguration Problems
Abstract
We present the first results on the parameterized complexity of reconfiguration problems, where a reconfiguration version of an optimization problem takes as input two feasible solutions and and determines if there is a sequence of {\em reconfiguration steps} that can be applied to transform into such that each step results in a feasible solution to . For most of the results in this paper, and are subsets of vertices of a given graph and a reconfiguration step adds or deletes a vertex. Our study is motivated by recent results establishing that for most NP-hard problems, the classical complexity of reconfiguration is PSPACE-complete. We address the question for several important graph properties under two natural parameterizations: , the size of the solutions, and , the length of the sequence of steps. Our first general result is an algorithmic paradigm, the {\em reconfiguration kernel}, used to obtain fixed-parameter algorithms for the reconfiguration versions of {\sc Vertex Cover} and, more generally, {\sc Bounded Hitting Set} and {\sc Feedback Vertex Set}, all parameterized by . In contrast, we show that reconfiguring {\sc Unbounded Hitting Set} is -hard when parameterized by . We also demonstrate the -hardness of the reconfiguration versions of a large class of maximization problems parameterized by , and of their corresponding deletion problems parameterized by ; in doing so, we show that there exist problems in FPT when parameterized by , but whose reconfiguration versions are -hard when parameterized by .
Cite
@article{arxiv.1308.2409,
title = {On the Parameterized Complexity of Reconfiguration Problems},
author = {Amer E. Mouawad and Naomi Nishimura and Venkatesh Raman and Narges Simjour and Akira Suzuki},
journal= {arXiv preprint arXiv:1308.2409},
year = {2013}
}
Comments
IPEC 2013