Graph Square Roots of Small Distance from Degree One Graphs

Abstract

Given a graph class H, the task of the H-Square Root problem is to decide, whether an input graph G has a square root H from H. We are interested in the parameterized complexity of the problem for classes H that are composed by the graphs at vertex deletion distance at most k from graphs of maximum degree at most one, that is, we are looking for a square root H such that there is a modulator S of size k such that H-S is the disjoint union of isolated vertices and disjoint edges. We show that different variants of the problems with constraints on the number of isolated vertices and edges in H-S are FPT when parameterized by k by demonstrating algorithms with running time 22O(k)· nO(1). We further show that the running time of our algorithms is asymptotically optimal and it is unlikely that the double-exponential dependence on k could be avoided. In particular, we prove that the VC-k Root problem, that asks whether an input graph has a square root with vertex cover of size at most k, cannot be solved in time 22o(k)· nO(1) unless Exponential Time Hypothesis fails. Moreover, we point out that VC-k Root parameterized by k does not admit a subexponential kernel unless P=NP.