Abstract
Impagliazzo et al. proposed a framework, based on the logic fragment defining the complexity class SNP, to identify problems that are equivalent to k -CNF- Sat modulo subexponential-time reducibility (serf-reducibility). The subexponential-time solvability of any of these problems implies the failure of the Exponential Time Hypothesis (ETH). In this article, we extend the framework of Impagliazzo et al. and identify a larger set of problems that are equivalent to k -CNF- Sat modulo serf-reducibility. We propose a complexity class, referred to as Linear Monadic NP, that consists of all problems expressible in existential monadic second-order logic whose expressions have a linear measure in terms of a complexity parameter, which is usually the universe size of the problem. This research direction can be traced back to Fagin’s celebrated theorem stating that NP coincides with the class of problems expressible in existential second-order logic. Monadic NP, a well-studied class in the literature, is the restriction of the aforementioned logic fragment to existential monadic second-order logic. The proposed class Linear Monadic NP is then the restriction of Monadic NP to problems whose expressions have linear measure in the complexity parameter. We show that Linear Monadic NP includes many natural complete problems such as the satisfiability of linear-size circuits, dominating set, independent dominating set, and perfect code. Therefore, for any of these problems, its subexponential-time solvability is equivalent to the failure of ETH. We prove, using logic games, that the aforementioned problems are inexpressible in the monadic fragment of SNP, and hence, are not captured by the framework of Impagliazzo et al. Finally, we show that Feedback Vertex Set is inexpressible in existential monadic second-order logic, and hence is not in Linear Monadic NP, and investigate the existence of certain reductions between Feedback Vertex Set (and variants of it) and 3-CNF-Sat .
Highlights
Motivation and related workThe area of exact algorithms seeks moderately exponential-time algorithms for NP-hard problems that improve on the trivial brute-force algorithms
We prove, using logic games, that the aforementioned problems are inexpressible in the monadic fragment of SNP, and are not captured by the framework of Impagliazzo et al we show that Feedback Vertex Set is inexpressible in existential monadic second order logic, and is not in Linear Monadic NP, and investigate the existence of certain reductions between Feedback Vertex Set and 3-CNF-Sat
There is a large set of important NP-complete problems such that for each problem there is a long list of exact algorithms, each improving slightly on the running time of the preceding one; we refer the interested reader to [19] for exposure to the area of exact algorithms
Summary
The area of exact algorithms seeks moderately exponential-time algorithms for NP-hard problems that improve on the trivial brute-force algorithms. We prove that problems such as Linear Circuit-Sat, Dominating Set, and Independent Dominating set are in Linear Monadic NP (and are complete for Linear Monadic NP), but are not expressible in the SNP logic, showing that the set of problems expressible in the SNP logic with a linear complexity parameter is a proper subset of Linear Monadic NP This implies that the subexponential-time solvability of any of the aforementioned problems is equivalent to the failure of ETH. We show that there is a polynomial-time reduction from Feedback Vertex Set to 3-CNF-Sat with a quasi-linear increase in the universe size, and define a variant of Feedback Vertex Set that is equivalent to 3-CNF-Sat under serf-reducibility
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