A polynomial restriction lemma with applications

Valentine Kabanets, D. Kane, Zhenjian Lu
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引用次数: 10

Abstract

A polynomial threshold function (PTF) of degree d is a boolean function of the form f=sgn(p), where p is a degree-d polynomial, and sgn is the sign function. The main result of the paper is an almost optimal bound on the probability that a random restriction of a PTF is not close to a constant function, where a boolean function g is called δ-close to constant if, for some vε{1,-1}, we have g(x)=v for all but at most δ fraction of inputs. We show for every PTF f of degree d≥ 1, and parameters 0<δ, r≤ 1/16, that Pr∾ Rr [fρ is not δ-close to constant] ≤ √ #183;(logr-1· logδ-1)O(d2), where ρ ∾ Rr is a random restriction leaving each variable, independently, free with probability r, and otherwise assigning it 1 or -1 uniformly at random. In fact, we show a more general result for random block restrictions: given an arbitrary partitioning of input variables into m blocks, a random block restriction picks a uniformly random block ℓΕ [m] and assigns 1 or -1, uniformly at random, to all variable outside the chosen block ℓ. We prove the Block Restriction Lemma saying that a PTF f of degree d becomes δ-close to constant when hit with a random block restriction, except with probability at most m-1/2 #183; (logm#183; logδ-1)O(d2). As an application of our Restriction Lemma, we prove lower bounds against constant-depth circuits with PTF gates of any degree 1≤ d≪ √logn/loglogn, generalizing the recent bounds against constant-depth circuits with linear threshold gates (LTF gates) proved by Kane and Williams (STOC, 2016) and Chen, Santhanam, and Srinivasan (CCC, 2016). In particular, we show that there is an n-variate boolean function Fn Ε P such that every depth-2 circuit with PTF gates of degree d≥ 1 that computes Fn must have at least (n3/2+1/d)#183; (logn)-O(d2) wires. For constant depths greater than 2, we also show average-case lower bounds for such circuits with super-linear number of wires. These are the first super-linear bounds on the number of wires for circuits with PTF gates. We also give short proofs of the optimal-exponent average sensitivity bound for degree-d PTFs due to Kane (Computational Complexity, 2014), and the Littlewood-Offord type anticoncentration bound for degree-d multilinear polynomials due to Meka, Nguyen, and Vu (Theory of Computing, 2016). Finally, we give derandomized versions of our Block Restriction Lemma and Littlewood-Offord type anticoncentration bounds, using a pseudorandom generator for PTFs due to Meka and Zuckerman (SICOMP, 2013).
一个多项式限制引理及其应用
d次的多项式阈值函数(PTF)是形式为f=sgn(p)的布尔函数,其中p是d次多项式,sgn是符号函数。本文的主要结果是一个关于PTF的随机约束不接近常数函数的概率的几乎最优界,其中布尔函数g被称为δ-接近常数,如果对于某些vε{1,-1},我们有g(x)=v,除了最多δ分数的输入。我们表明,对于每一个d度≥1,参数0<δ, r≤1/16的PTF f, Pr≈Rr [fρ不是δ-接近常数]≤√#183;(log -1·logδ-1)O(d2),其中ρ≈Rr是一个随机限制,使每个变量独立地以概率r自由,否则随机地均匀分配1或-1。事实上,我们展示了随机块限制的一个更一般的结果:给定输入变量的任意划分为m个块,随机块限制选择一个均匀随机块,并将1或-1均匀随机地分配给所选块之外的所有变量。Ε [m]我们证明了块限制引理,即d次的PTF f在被随机块限制击中时,除了概率不超过m-1/2 #183外,变得δ-接近常数;(logm # 183;日志δ1)O (d2)。作为我们的限制引理的应用,我们证明了具有任意阶1≤d≪√logn/loglogn的PTF门的定深电路的下界,推广了最近由Kane和Williams (STOC, 2016)以及Chen、Santhanam和Srinivasan (CCC, 2016)证明的具有线性阈值门(LTF门)的定深电路的下界。特别地,我们证明了存在一个n变量布尔函数Fn Ε P,使得每个计算Fn的深度2电路的PTF门的度数d≥1必须至少有(n2 /2+1/d)#183;(logn) - o (d2)电线。对于大于2的恒定深度,我们还给出了具有超线性导线数的这种电路的平均情况下界。这是具有PTF门的电路的导线数量的第一个超线性界限。我们还简要证明了Kane (Computational Complexity, 2014)提出的d度ptf的最佳指数平均灵敏度界,以及Meka、Nguyen和Vu提出的d度多线性多项式的littlewood - offford型反集中界(Theory of Computing, 2016)。最后,我们给出了块限制引理和littlewood - offford型反集中界的非随机化版本,使用Meka和Zuckerman (SICOMP, 2013)的伪随机ptf生成器。
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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