New Spectral Algorithms for Refuting Smoothed k-SAT

Despite being a quintessential example of a hard problem, the quest for finding fast algorithms for deciding satisfiability of propositional formulas has occupied computer scientists both in theory and in practice. In this article, we survey recent progress on designing algorithms with strong refutation guarantees for smoothed instances of the k-SAT problem. Smoothed instances are formed by slight random perturbations of arbitrary instances, and their study is a way to bridge the gap between worst-case and average-case models of problem instances. Our methods yield new algorithms for smoothed k-SAT instances with guarantees that match those for the significantly simpler and well-studied model of random formulas. Additionally, they have led to a novel and unexpected line of attack on some longstanding extremal combinatorial problems in graph theory and coding theory. As an example, we will discuss the resolution of a 2008 conjecture of Feige on the existence of short cycles in hypergraphs.