Proof complexity lower bounds from algebraic circuit complexity

Michael Forbes, Amir Shpilka, Iddo Tzameret, Avi Wigderson

Research output: Chapter in Book/Report/Conference proceedingConference contribution

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Abstract

We give upper and lower bounds on the power of subsystems of the Ideal Proof System (IPS), the algebraic proof system recently proposed by Grochow and Pitassi~\cite{GrochowPitassi14}, where the circuits comprising the proof come from various restricted algebraic circuit classes. This mimics an established research direction in the boolean setting for subsystems of Frege proofs whose lines are circuits from restricted boolean circuit classes. Essentially all of the subsystems considered in this paper can simulate the well-studied Nullstellensatz proof system, and prior to this work there were no known lower bounds when measuring proof size by the algebraic complexity of the polynomials (except with respect to degree, or to sparsity).

Our main contributions are two general methods of converting certain algebraic lower bounds into proof complexity ones. Both require stronger arithmetic lower bounds than common, which should hold not for a specific polynomial but for a whole family defined by it.
These may be likened to some of the methods by which Boolean circuit lower bounds are turned into related proof-complexity ones, especially the ``feasible interpolation'' technique. We establish algebraic lower bounds of these forms for several explicit polynomials, against a variety of classes, and infer the relevant proof complexity bounds. These yield separations between IPS subsystems, which we complement by simulations to create a partial structure theory for IPS systems.

Our first method is a \emph{functional lower bound}, a notion of Grigoriev and Razborov~\cite{GrigorievRazborov00}, which is a function $\hat{f}:\bits^n\to\F$ such that any polynomial $f$ agreeing with $\hat{f}$ on the boolean cube requires large algebraic circuit complexity. We develop functional lower bounds for a variety of circuit classes (sparse polynomials, depth-3 powering formulas, roABPs and multilinear formulas) where $\hat{f}(\vx)$ equals $\nicefrac{1}{p(\vx)}$ for a constant-degree polynomial $p$ depending on the relevant circuit class. We believe these lower bounds are of independent interest in algebraic complexity, and show that they also imply lower bounds for the size of the corresponding IPS refutations for proving that the relevant polynomial $p$ is non-zero over the boolean cube. In particular, we show super-polynomial lower bounds for refuting variants of the subset-sum axioms in these IPS subsystems.

Our second method is to give \emph{lower bounds for multiples}, that is, to give explicit polynomials whose all (non-zero) multiples require large algebraic circuit complexity. By extending known techniques, we give lower bounds for multiples for various restricted circuit classes such sparse polynomials, sums of powers of low-degree polynomials, and roABPs. These results are of independent interest, as we argue that lower bounds for multiples is the correct notion for instantiating the algebraic hardness versus randomness paradigm of Kabanets and Impagliazzo~\cite{KabanetsImpagliazzo04}. Further, we show how such lower bounds for multiples extend to lower bounds for refutations in the corresponding IPS subsystem.
Original languageEnglish
Title of host publication31st Conference on Computational Complexity (CCC 2016)
Place of PublicationDagstuhl, Germany
PublisherSchloss Dagstuhl--Leibniz-Zentrum fuer Informatik
Pages1-17
Number of pages17
Volume50
ISBN (Print)978-3-95977-008-8
DOIs
Publication statusPublished - 19 May 2016
EventComputational Complexity Conference (CCC) - Japan, Koyto, Japan
Duration: 29 May 20161 Jun 2016

Publication series

NameLeibniz International Proceedings in Informatics (LIPIcs)
PublisherSchloss Dagstuhl--Leibniz-Zentrum fuer Informatik
Volume50
ISSN (Print)1868-8969

Conference

ConferenceComputational Complexity Conference (CCC)
Country/TerritoryJapan
CityKoyto
Period29/05/161/06/16

Keywords

  • complexity theory

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