MaxSAT Resolution and Subcube Sums

IF 0.7 4区数学 Q3 COMPUTER SCIENCE, THEORY & METHODS ACM Transactions on Computational Logic Pub Date : 2023-01-18 DOI:https://dl.acm.org/doi/10.1145/3565363

Yuval Filmus, Meena Mahajan, Gaurav Sood, Marc Vinyals

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Abstract

We study the MaxSAT Resolution (MaxRes) rule in the context of certifying unsatisfiability. We show that it can be exponentially more powerful than tree-like resolution, and when augmented with weakening (the system MaxResW), p-simulates tree-like resolution. In devising a lower bound technique specific to MaxRes (and not merely inheriting lower bounds from Res), we define a new proof system called the SubCubeSums proof system. This system, which p-simulates MaxResW, can be viewed as a special case of the semi-algebraic Sherali–Adams proof system. In expressivity, it is the integral restriction of conical juntas studied in the contexts of communication complexity and extension complexity. We show that it is not simulated by Res. Using a proof technique qualitatively different from the lower bounds that MaxResW inherits from Res, we show that Tseitin contradictions on expander graphs are hard to refute in SubCubeSums. We also establish a lower bound technique via lifting: for formulas requiring large degree in SubCubeSums, their XOR-ification requires large size in SubCubeSums.

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MaxSAT分辨率和子立方体和

我们研究了在不满意性认证背景下的MaxSAT分辨率(MaxRes)规则。我们证明它可以比树状分辨率指数更强大，并且当增强削弱(系统MaxResW)时，p模拟树状分辨率。在设计特定于MaxRes的下界技术(而不仅仅是继承Res的下界)时，我们定义了一个称为SubCubeSums证明系统的新证明系统。该系统p模拟了MaxResW，可以看作是半代数Sherali-Adams证明系统的一个特例。在表达性方面，它是在交际复杂性和可拓复杂性的背景下所研究的锥形群体的整体限制。使用一种与MaxResW从Res继承的下界定性不同的证明技术，我们证明了在subcubesum中扩展图上的tseittin矛盾很难被反驳。我们还通过提升建立了下界技术:对于在SubCubeSums中需要大度的公式，其异或化需要在SubCubeSums中使用大尺寸。

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来源期刊

ACM Transactions on Computational Logic 工程技术-计算机：理论方法

CiteScore

2.30

自引率

0.00%

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审稿时长

>12 weeks

期刊介绍： TOCL welcomes submissions related to all aspects of logic as it pertains to topics in computer science. This area has a great tradition in computer science. Several researchers who earned the ACM Turing award have also contributed to this field, namely Edgar Codd (relational database systems), Stephen Cook (complexity of logical theories), Edsger W. Dijkstra, Robert W. Floyd, Tony Hoare, Amir Pnueli, Dana Scott, Edmond M. Clarke, Allen E. Emerson, and Joseph Sifakis (program logics, program derivation and verification, programming languages semantics), Robin Milner (interactive theorem proving, concurrency calculi, and functional programming), and John McCarthy (functional programming and logics in AI). Logic continues to play an important role in computer science and has permeated several of its areas, including artificial intelligence, computational complexity, database systems, and programming languages. The Editorial Board of this journal seeks and hopes to attract high-quality submissions in all the above-mentioned areas of computational logic so that TOCL becomes the standard reference in the field. Both theoretical and applied papers are sought. Submissions showing novel use of logic in computer science are especially welcome.

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