Biased halfspaces, noise sensitivity, and local Chernoff inequalities

IF 1 3区数学 Q1 MATHEMATICS

Discrete Analysis Pub Date : 2017-10-01 DOI:10.19086/DA.10234

Nathan Keller, Ohad Klein

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Abstract

A halfspace is a function $f\colon\{-1,1\}^n \rightarrow \{0,1\}$ of the form $f(x)=\mathbb{1}(a\cdot x>t)$, where $\sum_i a_i^2=1$. We show that if $f$ is a halfspace with $\mathbb{E}[f]=\epsilon$ and $a'=\max_i |a_i|$, then the degree-1 Fourier weight of $f$ is $W^1(f)=\Theta(\epsilon^2 \log(1/\epsilon))$, and the maximal influence of $f$ is $I_{\max}(f)=\Theta(\epsilon \min(1,a' \sqrt{\log(1/\epsilon)}))$. These results, which determine the exact asymptotic order of $W^1(f)$ and $I_{\max}(f)$, provide sharp generalizations of theorems proved by Matulef, O'Donnell, Rubinfeld, and Servedio, and settle a conjecture posed by Kalai, Keller and Mossel. In addition, we present a refinement of the definition of noise sensitivity which takes into consideration the bias of the function, and show that (like in the unbiased case) halfspaces are noise resistant, and, in the other direction, any noise resistant function is well correlated with a halfspace. Our main tools are 'local' forms of the classical Chernoff inequality, like the following one proved by Devroye and Lugosi (2008): Let $\{ x_i \}$ be independent random variables uniformly distributed in $\{-1,1\}$, and let $a_i\in\mathbb{R}_+$ be such that $\sum_i a_{i}^{2}=1$. If for some $t\geq 0$ we have $\Pr[\sum_{i} a_i x_i > t]=\epsilon$, then $\Pr[\sum_{i} a_i x_i>t+\delta]\leq \frac{\epsilon}{2}$ holds for $\delta\leq c/\sqrt{\log(1/\epsilon)}$, where $c$ is a universal constant.

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有偏半空间、噪声敏感性和局部Chernoff不等式

半空间是形式为$f（x）=\mathbb｛1｝（A\cdot x>t）$的函数$f\colon\｛-1，1\｝^n\rightarrow\｛0,1\｝$，其中$\sum_ia_i^2=1$。我们证明，如果$f$是具有$\mathbb｛E｝[f]=\epsilon$和$a'=\max_i|a_i|$的半空间，则$f$的1阶傅立叶权重为$W^1（f）=\Theta（\epsilon^2 \log（1/\epsilon））$，并且$f$最大影响为$i_｛\max｝（f）=\Theta。这些结果确定了$W^1（f）$和$I_。此外，我们提出了噪声灵敏度定义的改进，该定义考虑了函数的偏差，并表明（与无偏情况一样）半空间是抗噪声的，并且在另一个方向上，任何抗噪声函数都与半空间良好相关。我们的主要工具是经典Chernoff不等式的“局部”形式，如Devroye和Lugosi（2008）证明的以下形式：设$\{x_i\}$是均匀分布在$\{-1,1\}$中的独立随机变量，并设$a_i\in\mathbb{R}_+$使得$\sum_ia_｛i｝^｛2｝=1$。如果对于一些$t\geq0$，我们有$\Pr[\sum_｛i｝a_i x_i>t]=\epsilon$，那么$\Pr[[sum_{i｝a_ix_i>t+\delta]\leq\frac｛\epsilon｝｛2｝$对于$\delta\leq c/\sqrt｛\log（1/\epsilon）｝$成立，其中$c$是一个通用常数。

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来源期刊

Discrete Analysis Mathematics-Algebra and Number Theory

CiteScore

1.60

自引率

0.00%

发文量

审稿时长

17 weeks

期刊介绍： Discrete Analysis is a mathematical journal that aims to publish articles that are analytical in flavour but that also have an impact on the study of discrete structures. The areas covered include (all or parts of) harmonic analysis, ergodic theory, topological dynamics, growth in groups, analytic number theory, additive combinatorics, combinatorial number theory, extremal and probabilistic combinatorics, combinatorial geometry, convexity, metric geometry, and theoretical computer science. As a rough guideline, we are looking for papers that are likely to be of genuine interest to the editors of the journal.