Hardness of Approximation for H-free Edge Modification Problems

The H-free Edge Deletion problem asks, for a given graph G and integer k, whether it is possible to delete at most k edges from G to make it H-free—that is, not containing H as an induced subgraph. The H-free Edge Completion problem is defined similarly, but we add edges instead of deleting them. The study of these two problem families has recently been the subject of intensive studies from the point of view of parameterized complexity and kernelization. In particular, it was shown that the problems do not admit polynomial kernels (under plausible complexity assumptions) for almost all graphs H, with several important exceptions occurring when the class of H-free graphs exhibits some structural properties. In this work, we complement the parameterized study of edge modification problems to H-free graphs by considering their approximability. We prove that whenever H is 3-connected and has at least two nonedges, then both H-free Edge Deletion and H-free Edge Completion are very hard to approximate: they do not admit poly(OPT)-approximation in polynomial time, unless P=NP, or even in time subexponential in OPT, unless the exponential time hypothesis fails. The assumption of the existence of two nonedges appears to be important: we show that whenever H is a complete graph without one edge, then H-free Edge Deletion is tightly connected to the Min Horn Deletion problem, whose approximability is still open. Finally, in an attempt to extend our hardness results beyond 3-connected graphs, we consider the cases of H being a path or a cycle, and we achieve an almost complete dichotomy there.

[1]  Haim Kaplan,et al.  Tractability of Parameterized Completion Problems on Chordal, Strongly Chordal, and Proper Interval Graphs , 1999, SIAM J. Comput..

[2]  Leizhen Cai,et al.  Incompressibility of $$H$$H-Free Edge Modification Problems , 2014, Algorithmica.

[3]  Leizhen Cai,et al.  Incompressibility of H-Free Edge Modification , 2013, IPEC.

[4]  Marek Cygan,et al.  Lower Bounds for the Parameterized Complexity of Minimum Fill-in and Other Completion Problems , 2020, ACM Trans. Algorithms.

[5]  Saket Saurabh,et al.  Tree Deletion Set Has a Polynomial Kernel but No OPTO(1) Approximation , 2013, SIAM J. Discret. Math..

[6]  Saket Saurabh,et al.  Tree Deletion Set Has a Polynomial Kernel (but no OPT^O(1) Approximation) , 2014, FSTTCS.

[7]  Erik Jan van Leeuwen,et al.  Polynomial Kernelization for Removing Induced Claws and Diamonds , 2015, Theory of Computing Systems.

[8]  Naveen Sivadasan,et al.  Dichotomy Results on the Hardness of H-free Edge Modification Problems , 2017, SIAM J. Discret. Math..

[9]  Russell Impagliazzo,et al.  Complexity of k-SAT , 1999, Proceedings. Fourteenth Annual IEEE Conference on Computational Complexity (Formerly: Structure in Complexity Theory Conference) (Cat.No.99CB36317).

[10]  Michal Pilipczuk,et al.  Exploring the Subexponential Complexity of Completion Problems , 2015, TOCT.

[11]  Naveen Sivadasan,et al.  Parameterized lower bound and improved kernel for Diamond-free Edge Deletion , 2015, IPEC.

[12]  Leizhen Cai,et al.  Fixed-Parameter Tractability of Graph Modification Problems for Hereditary Properties , 1996, Inf. Process. Lett..

[13]  Luca Trevisan,et al.  The Approximability of Constraint Satisfaction Problems , 2001, SIAM J. Comput..

[14]  Stefan Kratsch,et al.  Two edge modification problems without polynomial kernels , 2009, Discret. Optim..

[15]  Christophe Paul,et al.  On the (Non-)Existence of Polynomial Kernels for Pl-Free Edge Modification Problems , 2010, Algorithmica.

[16]  Naveen Sivadasan,et al.  Parameterized Lower Bound and NP-Completeness of Some H-Free Edge Deletion Problems , 2015, COCOA.

[17]  Dániel Marx,et al.  Lower bounds based on the Exponential Time Hypothesis , 2011, Bull. EATCS.