Sparser Random 3-SAT Refutation Algorithms and the Interpolation Problem

Tzameret, Iddo

doi:10.1007/978-3-662-43948-7_84

Automata, Languages, and Programming

2014

DOI: 10.1007/978-3-662-43948-7_84

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Sparser Random 3-SAT Refutation Algorithms and the Interpolation Problem

Iddo Tzameret

Abstract: We formalize a combinatorial principle, called the 3XOR principle, due to Feige, Kim and Ofek [14], as a family of unsatisfiable propositional formulas for which refutations of small size in any propositional proof system that possesses the feasible interpolation property imply an efficient deterministic refutation algorithm for random 3SAT with n variables and Ω(n 1.4 ) clauses. Such small size refutations would improve the state of the art (with respect to the clause density) efficient refutation algorithm,… Show more

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On Proof Complexity of Resolution over Polynomial Calculus

Khaniki

2022

ACM Trans. Comput. Logic

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The proof system Res (PC d,R ) is a natural extension of the Resolution proof system that instead of disjunctions of literals operates with disjunctions of degree d multivariate polynomials over a ring R with Boolean variables. Proving super-polynomial lower bounds for the size of Res ( PC 1, R )-refutations of Conjunctive normal forms (CNFs) is one of the important problems in propositional proof complexity. The existence of such lower bounds is even open for Res ( PC 1,𝔽 ) when 𝔽 is a finite field, such as 𝔽 2 . In this article, we investigate Res ( PC d,R ) and tree-like Res ( PC d,R ) and prove size-width relations for them when R is a finite ring. As an application, we prove new lower bounds and reprove some known lower bounds for every finite field 𝔽 as follows: (1) We prove almost quadratic lower bounds for Res ( PC d ,𝔽)-refutations for every fixed d . The new lower bounds are for the following CNFs: (a) Mod q Tseitin formulas ( char (𝔽)≠ q ) and Flow formulas, (b) Random k -CNFs with linearly many clauses. (2) We also prove super-polynomial (more than n k for any fixed k ) and also exponential (2 nϵ for an ϵ > 0) lower bounds for tree-like Res ( PC d ,𝔽 )-refutations based on how big d is with respect to n for the following CNFs: (a) Mod q Tseitin formulas ( char (𝔽)≠ q ) and Flow formulas, (b) Random k -CNFs of suitable densities, (c) Pigeonhole principle and Counting mod q principle. The lower bounds for the dag-like systems are the first nontrivial lower bounds for these systems, including the case d =1. The lower bounds for the tree-like systems were known for the case d =1 (except for the Counting mod q principle, in which lower bounds for the case d > 1 were known too). Our lower bounds extend those results to the case where d > 1 and also give new proofs for the case d =1.

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On Proof Complexity of Resolution over Polynomial Calculus

Khaniki

2022

ACM Trans. Comput. Logic

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show abstract

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Sparser Random 3-SAT Refutation Algorithms and the Interpolation Problem

Cited by 1 publication

References 40 publications

On Proof Complexity of Resolution over Polynomial Calculus

On Proof Complexity of Resolution over Polynomial Calculus

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