English

Gap Amplification for Reconfiguration Problems

Discrete Mathematics 2024-03-19 v2 Computational Complexity

Abstract

In this paper, we demonstrate gap amplification for reconfiguration problems. In particular, we prove an explicit factor of PSPACE-hardness of approximation for three popular reconfiguration problems only assuming the Reconfiguration Inapproximability Hypothesis (RIH) due to Ohsaka (STACS 2023). Our main result is that under RIH, Maxmin 2-CSP Reconfiguration is PSPACE-hard to approximate within a factor of 0.99420.9942. Moreover, the same result holds even if the constraint graph is restricted to (d,λ)(d,\lambda)-expander for arbitrarily small λd\frac{\lambda}{d}. The crux of its proof is an alteration of the gap amplification technique due to Dinur (J. ACM, 2007), which amplifies the 11 vs. 1ε1-\varepsilon gap for arbitrarily small ε(0,1)\varepsilon \in (0,1) up to the 11 vs. 10.00581-0.0058 gap. As an application of the main result, we demonstrate that Minmax Set Cover Reconfiguration and Minmax Dominating Set Reconfiguratio} are PSPACE-hard to approximate within a factor of 1.00291.0029 under RIH. Our proof is based on a gap-preserving reduction from Label Cover to Set Cover due to Lund and Yannakakis (J. ACM, 1994). Unlike Lund--Yannakakis' reduction, the expander mixing lemma is essential to use. We highlight that all results hold unconditionally as long as "PSPACE-hard" is replaced by "NP-hard," and are the first explicit inapproximability results for reconfiguration problems without resorting to the parallel repetition theorem. We finally complement the main result by showing that it is NP-hard to approximate Maxmin 2-CSP Reconfiguration within a factor better than 34\frac{3}{4}.

Keywords

Cite

@article{arxiv.2310.14160,
  title  = {Gap Amplification for Reconfiguration Problems},
  author = {Naoto Ohsaka},
  journal= {arXiv preprint arXiv:2310.14160},
  year   = {2024}
}

Comments

45 pages. A preliminary version of this paper appeared in Proc. 35th Annu. ACM-SIAM Symp. Discrete Algorithms (SODA 2024)

R2 v1 2026-06-28T12:57:51.672Z