Reconstruction of Generalized Depth-3 Arithmetic Circuits with Bounded Top Fan-in

2009 24th Annual IEEE Conference on Computational Complexity Pub Date : 2009-07-15 DOI:10.1109/CCC.2009.18

Zohar S. Karnin, Amir Shpilka

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引用次数: 51

Abstract

In this paper we give reconstruction algorithms for depth-3 arithmetic circuits with $k$ multiplication gates (also known as $\Sigma\Pi\Sigma(k)$ circuits), where $k=O(1)$. Namely, we give an algorithm that when given a black box holding a $\Sigma\Pi\Sigma(k)$ circuit $C$ over a field $\F$ as input, makes queries to the black box (possibly over a polynomial sized extension field of $\F$) and outputs a circuit $C'$ computing the same polynomial as $C$. In particular we obtain the following results. 1) When $C$ is a multilinear $\Sigma\Pi\Sigma(k)$ circuit (i.e. each of its multiplication gates computes a multilinear polynomial) then our algorithm runs in polynomial time (when $k$ is a constant) and outputs a multilinear $\Sigma\Pi\Sigma(k)$ circuits computing the same polynomial. 2) In the general case, our algorithm runs in quasi-polynomial time and outputs a generalized depth-3 circuit (as defined in \cite{KarninShpilka08}) with $k$ multiplication gates. For example, the polynomials computed by generalized depth-3 circuits can be computed by quasi-polynomial sized depth-3 circuits. In fact, our algorithm works in the slightly more general case where the black box holds a generalized depth-3 circuits. Prior to this work there were reconstruction algorithms for several different models of bounded depth circuits: the well studied class of depth-2 arithmetic circuits (that compute sparse polynomials) and its close by model of depth-3 set-multilinear circuits. For the class of depth-3 circuits only the case of $k=2$ (i.e. $\Sigma\Pi\Sigma(2)$ circuits) was known. Our proof technique combines ideas from [Shpilka09] and [KarninShpilka08] with some new ideas. Our most notable new ideas are: We prove the existence of a unique canonical representation of depth-3 circuits. This enables us to work with a specific representation in mind. Another technical contribution is an isolation lemma for depth-3 circuits that enables us to reconstruct a single multiplication gate of the circuit.

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具有有界顶部扇入的广义深度-3算术电路的重构

本文给出了具有$k$乘法门(也称为$\Sigma\Pi\Sigma(k)$电路)的深度3算术电路的重构算法，其中$k=O(1)$。也就是说，我们给出了一种算法，当给定一个黑盒子，其中包含一个$\Sigma\Pi\Sigma(k)$电路$C$作为输入字段$\F$时，对黑盒子进行查询(可能是在一个多项式大小的扩展字段$\F$上)，并输出一个电路$C'$，计算与$C$相同的多项式。特别地，我们得到了以下结果。1)当$C$是一个多线性$\Sigma\Pi\Sigma(k)$电路(即它的每个乘法门计算一个多线性多项式)，那么我们的算法运行在多项式时间(当$k$是一个常数)，并输出一个计算相同多项式的多线性$\Sigma\Pi\Sigma(k)$电路。2)在一般情况下，我们的算法在准多项式时间内运行，并输出一个具有$k$乘法门的广义深度-3电路(如\cite{KarninShpilka08}中定义的)。例如，广义深度-3电路计算的多项式可以用拟多项式大小的深度-3电路计算。事实上，我们的算法适用于更一般的情况，即黑箱中有一个广义深度3的电路。在此工作之前，有几种不同的有界深度电路模型的重建算法:深度-2算术电路(计算稀疏多项式)和深度-3集多线性电路的接近模型。对于深度3电路的类别，只知道$k=2$(即$\Sigma\Pi\Sigma(2)$电路)的情况。我们的证明技术结合了[Shpilka09]和[KarninShpilka08]的想法和一些新的想法。我们最值得注意的新思想是:我们证明了深度-3电路的唯一规范表示的存在性。这使我们能够在头脑中使用特定的表示。另一个技术贡献是深度3电路的隔离引理，使我们能够重建电路的单个乘法门。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2009 24th Annual IEEE Conference on Computational Complexity

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