Hardness Characterisations and Size-width Lower Bounds for QBF Resolution

Author:

Beyersdorff Olaf1,Blinkhorn Joshua1,Mahajan Meena2,Peitl Tomáš3

Affiliation:

1. Friedrich-Schiller-Universität Jena, Germany

2. The Institute of Mathematical Sciences, HBNI, Chennai, India

3. TU Wienm, Vienna, Austria

Abstract

We provide a tight characterisation of proof size in resolution for quantified Boolean formulas (QBF) via circuit complexity. Such a characterisation was previously obtained for a hierarchy of QBF Frege systems [ 16 ], but leaving open the most important case of QBF resolution. Different from the Frege case, our characterisation uses a new version of decision lists as its circuit model, which is stronger than the CNFs the system works with. Our decision list model is well suited to compute countermodels for QBFs. Our characterisation works for both Q-Resolution and QU-Resolution. Using our characterisation, we obtain a size-width relation for QBF resolution in the spirit of the celebrated result for propositional resolution [ 4 ]. However, our result is not just a replication of the propositional relation—intriguingly ruled out for QBF in previous research [ 12 ]—but shows a different dependence between size, width, and quantifier complexity. An essential ingredient is an improved relation between the size and width of term decision lists; this may be of independent interest. We demonstrate that our new technique elegantly reproves known QBF hardness results and unifies previous lower-bound techniques in the QBF domain.

Funder

John Templeton Foundation JTF

DFG

Austrian Science Fund FWF FWF

Carl Zeiss Foundation CZF

Publisher

Association for Computing Machinery (ACM)

Subject

Computational Mathematics,Logic,General Computer Science,Theoretical Computer Science

Reference49 articles.

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3. Paul Beame and Toniann Pitassi. 2001. Propositional proof complexity: Past, present, and future. In Current Trends in Theoretical Computer Science: Entering the 21st Century, G. Paun, G. Rozenberg, and A. Salomaa (Eds.). World Scientific Publishing, UK, 42–70.

4. Short proofs are narrow—Resolution made simple;Ben-Sasson Eli;J. ACM,2001

5. On the correspondence between arithmetic theories and propositional proof systems—A survey;Beyersdorff Olaf;Math. Logic Quart.,2009

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