Product Space Models of Correlation: Between Noise Stability and Additive Combinatorics

IF 1 3区数学 Q1 MATHEMATICS

Discrete Analysis Pub Date : 2015-09-21 DOI:10.19086/da.6513

Jan Hkazla, Thomas Holenstein, Elchanan Mossel

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It is not hard to prove that this is equivalent to the statement that if $N$ is sufficiently large, then every function $f:\\mathbb Z_N\\to[0,1]$ (where $\\mathbb Z_N$ is the cyclic group of order $N$) with average value at least $\\mu$ satisfies an inequality of the form\n\n$$\\mathbb E_{x,d}f(x)f(x+d)\\dots f(x+(\\ell-1)d)\\geq \\delta$$\n\nwhere $\\delta$ is a positive constant that depends only on $\\mu$ and $\\ell$. \n\nWe can express this as a statement about a product of random variables, as follows. Let $x$ and $d$ be chosen uniformly at random and for each $1\\leq i\\leq\\ell$ let $X^{(i)}$ be the random variable that takes the value $x+(i-1)d$. Then for every function $f:\\mathbb Z_N$ that takes values in $[0,1]$, if $\\mathbb E[f(X^{(i)})]\\geq\\mu$ for each $i$, then we also have that $\\mathbb E f(X^{(1)})\\dots f(X^{(\\ell)})\\geq\\delta$. A sequence of random variables with this property is called _same-set hitting_. Note that the random variables $X^{(i)}$ here are not independent, but they are individually uniformly distributed. In particular, they are identically distributed.\n\nThe equivalent form of Szemeredi's theorem given above can be stated and proved for other Abelian groups. A particularly well-known case is when the group is $\\mathbb F_p^n$ for some fixed prime $p\\geq\\ell$. Here we can say more about the corresponding random variables $X^{(i)}$. Now they take values in $\\mathbb F_p^n$, and if for each coordinate $j$ we form the vector $\\underline{X}_j=(X^{(1)}_j,\\dots,X^{(\\ell)}_j)$, we find that the vectors $\\underline{X}_j$ are independent and identically distributed. Indeed, each one is a random (possibly degenerate) arithmetic progression in the group $\\mathbb F_p$. \n\nThe purpose of this paper is to consider this situation in general, and in particular to try to understand which systems of random variables $X^{(1)},\\dots,X^{(\\ell)}$ satisfying the above conditions are same-set hitting.\n\nA related concept, which also comes up in additive combinatorics, is that of being _set hitting_. This is the natural off-diagonal strengthening of being same-set hitting. That is, the random variables are set hitting if whenever $f_1,\\dots,f_\\ell$ are functions taking values in $[0,1]$ and $\\mathbb Ef_i(X^{(i)})\\geq\\mu$ for each $i$, we have that $\\mathbb Ef_1(X^{(1)})\\dots f_\\ell(X^{(\\ell)})\\geq\\delta$, where once again $\\delta$ depends only on $\\mu$ and $\\ell$.\n\nTo see that this is a considerably stronger property, one need only look at the case of random arithmetic progressions $(X^{(1)},X^{(2)},X^{(3)})$ of length 3 in $\\mathbb F_3^n$. If we let $f_1=f_2(x)=1$ if $x_1=0$ and $0$ otherwise, and $f_3(x)=1$ if $x_1=1$ and $0$ otherwise, then each $\\mathbb E f_i(X^{(i)})$ is equal to 1/3, but the product $f_1(X^{(1)})f_2(X^{(2)})f_3(X^{(3)})$ is identically zero.\n\nIt turns out to be useful in the theory of noise stability to characterize set hitting distributions, and this has been done. But it is harder to characterize same-set hitting distributions. One of the main results of the paper is a characterization in the case $\\ell=2$. This is already an interesting case: for example, a consequence of their results is the non-obvious fact that for all $\\mu>0$ there exists $\\delta>0$ such that if $A$ is a dense subset of $\\mathbb F_3^n$ and $(x,y)\\in\\mathbb F_3^n$ is chosen randomly from all pairs with the property that $y_j-x_j\\in\\{0,1\\}$ for every coordinate $j$, then with probability at least $\\delta$ both $x$ and $y$ belong to $A$. For $\\ell>2$, sufficient conditions are obtained.\n\nThe paper uses techniques from both additive combinatorics and the theory of noise sensitivity, combining the two fields in a new and interesting way. It also contains several interesting open problems.","PeriodicalId":37312,"journal":{"name":"Discrete Analysis","volume":null,"pages":null},"PeriodicalIF":1.0000,"publicationDate":"2015-09-21","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"6","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Discrete Analysis","FirstCategoryId":"100","ListUrlMain":"https://doi.org/10.19086/da.6513","RegionNum":3,"RegionCategory":"数学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"MATHEMATICS","Score":null,"Total":0}

引用次数: 6

Abstract

Product Space Models of Correlation: Between Noise Stability and Additive Combinatorics, Discrete Analysis 2018:20, 63 pp. Szemeredi's theorem states that for every positive integer $\ell$ and every $\mu>0$ there exists $N$ such that every subset of $\{1,2,\dots,N\}$ of density at least $\mu$ contains an arithmetic progression of length $\ell$. It is not hard to prove that this is equivalent to the statement that if $N$ is sufficiently large, then every function $f:\mathbb Z_N\to[0,1]$ (where $\mathbb Z_N$ is the cyclic group of order $N$) with average value at least $\mu$ satisfies an inequality of the form $$\mathbb E_{x,d}f(x)f(x+d)\dots f(x+(\ell-1)d)\geq \delta$$ where $\delta$ is a positive constant that depends only on $\mu$ and $\ell$. We can express this as a statement about a product of random variables, as follows. Let $x$ and $d$ be chosen uniformly at random and for each $1\leq i\leq\ell$ let $X^{(i)}$ be the random variable that takes the value $x+(i-1)d$. Then for every function $f:\mathbb Z_N$ that takes values in $[0,1]$, if $\mathbb E[f(X^{(i)})]\geq\mu$ for each $i$, then we also have that $\mathbb E f(X^{(1)})\dots f(X^{(\ell)})\geq\delta$. A sequence of random variables with this property is called _same-set hitting_. Note that the random variables $X^{(i)}$ here are not independent, but they are individually uniformly distributed. In particular, they are identically distributed. The equivalent form of Szemeredi's theorem given above can be stated and proved for other Abelian groups. A particularly well-known case is when the group is $\mathbb F_p^n$ for some fixed prime $p\geq\ell$. Here we can say more about the corresponding random variables $X^{(i)}$. Now they take values in $\mathbb F_p^n$, and if for each coordinate $j$ we form the vector $\underline{X}_j=(X^{(1)}_j,\dots,X^{(\ell)}_j)$, we find that the vectors $\underline{X}_j$ are independent and identically distributed. Indeed, each one is a random (possibly degenerate) arithmetic progression in the group $\mathbb F_p$. The purpose of this paper is to consider this situation in general, and in particular to try to understand which systems of random variables $X^{(1)},\dots,X^{(\ell)}$ satisfying the above conditions are same-set hitting. A related concept, which also comes up in additive combinatorics, is that of being _set hitting_. This is the natural off-diagonal strengthening of being same-set hitting. That is, the random variables are set hitting if whenever $f_1,\dots,f_\ell$ are functions taking values in $[0,1]$ and $\mathbb Ef_i(X^{(i)})\geq\mu$ for each $i$, we have that $\mathbb Ef_1(X^{(1)})\dots f_\ell(X^{(\ell)})\geq\delta$, where once again $\delta$ depends only on $\mu$ and $\ell$. To see that this is a considerably stronger property, one need only look at the case of random arithmetic progressions $(X^{(1)},X^{(2)},X^{(3)})$ of length 3 in $\mathbb F_3^n$. If we let $f_1=f_2(x)=1$ if $x_1=0$ and $0$ otherwise, and $f_3(x)=1$ if $x_1=1$ and $0$ otherwise, then each $\mathbb E f_i(X^{(i)})$ is equal to 1/3, but the product $f_1(X^{(1)})f_2(X^{(2)})f_3(X^{(3)})$ is identically zero. It turns out to be useful in the theory of noise stability to characterize set hitting distributions, and this has been done. But it is harder to characterize same-set hitting distributions. One of the main results of the paper is a characterization in the case $\ell=2$. This is already an interesting case: for example, a consequence of their results is the non-obvious fact that for all $\mu>0$ there exists $\delta>0$ such that if $A$ is a dense subset of $\mathbb F_3^n$ and $(x,y)\in\mathbb F_3^n$ is chosen randomly from all pairs with the property that $y_j-x_j\in\{0,1\}$ for every coordinate $j$, then with probability at least $\delta$ both $x$ and $y$ belong to $A$. For $\ell>2$, sufficient conditions are obtained. The paper uses techniques from both additive combinatorics and the theory of noise sensitivity, combining the two fields in a new and interesting way. It also contains several interesting open problems.

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相关的积空间模型:噪声稳定性与加性组合

szemeredi定理指出，对于每一个正整数$\ell$和每一个$\mu>0$，存在$N$，使得密度至少为$\mu$的$\{1,2,\dots,N\}$的每一个子集都包含长度为$\ell$的等比数列。不难证明，这等价于这样一个命题:如果$N$足够大，则每个函数$f:\mathbb Z_N\to[0,1]$(其中$\mathbb Z_N$是$N$阶的循环群)的平均值至少为$\mu$，满足如下形式的不等式:$$\mathbb E_{x,d}f(x)f(x+d)\dots f(x+(\ell-1)d)\geq \delta$$，其中$\delta$是一个仅依赖于$\mu$和$\ell$的正常数。我们可以将其表示为一个关于随机变量乘积的陈述，如下所示。设$x$和$d$均匀随机选择，对于每个$1\leq i\leq\ell$，设$X^{(i)}$为取值$x+(i-1)d$的随机变量。然后对于每个在$[0,1]$中取值的函数$f:\mathbb Z_N$，如果$\mathbb E[f(X^{(i)})]\geq\mu$对应每个$i$，那么我们也有$\mathbb E f(X^{(1)})\dots f(X^{(\ell)})\geq\delta$。具有此属性的随机变量序列称为＿same-set hitting＿。注意，这里的随机变量$X^{(i)}$不是独立的，而是单独均匀分布的。特别是，它们是均匀分布的。上述Szemeredi定理的等价形式也可用于其它阿贝尔群。一个特别著名的例子是，对于某个固定质数$p\geq\ell$，组是$\mathbb F_p^n$。这里我们可以说更多关于相应的随机变量$X^{(i)}$。现在它们在$\mathbb F_p^n$中取值，如果对于每个坐标$j$我们形成向量$\underline{X}_j=(X^{(1)}_j,\dots,X^{(\ell)}_j)$，我们发现向量$\underline{X}_j$是独立且分布相同的。实际上，每一个都是$\mathbb F_p$组中的一个随机的(可能是退化的)等差数列。本文的目的是一般考虑这种情况，特别是试图理解哪些随机变量系统$X^{(1)},\dots,X^{(\ell)}$满足上述条件是同集命中。一个相关的概念，也出现在加性组合学中，就是被集合击中。这是同局击球时自然的非对角线强化。也就是说，只要$f_1,\dots,f_\ell$是函数，每个$i$都取$[0,1]$和$\mathbb Ef_i(X^{(i)})\geq\mu$的值，我们就有$\mathbb Ef_1(X^{(1)})\dots f_\ell(X^{(\ell)})\geq\delta$，其中$\delta$再次依赖于$\mu$和$\ell$。为了看到这是一个相当强大的属性，我们只需要看看$\mathbb F_3^n$中长度为3的随机算术数列$(X^{(1)},X^{(2)},X^{(3)})$的情况。如果我们让$f_1=f_2(x)=1$等于$x_1=0$和$0$，如果$f_3(x)=1$等于$x_1=1$和$0$，那么每个$\mathbb E f_i(X^{(i)})$等于1/3，但是乘积$f_1(X^{(1)})f_2(X^{(2)})f_3(X^{(3)})$等于零。事实证明，在噪声稳定性理论中描述集合碰撞分布是有用的，这已经完成了。但是描述相同集合命中的分布是比较困难的。本文的主要结果之一是对$\ell=2$案例的描述。这已经是一个有趣的案例了:例如，他们的结果的一个结果是一个不明显的事实，即对于所有$\mu>0$存在$\delta>0$，如果$A$是$\mathbb F_3^n$的密集子集，并且$(x,y)\in\mathbb F_3^n$是从所有对中随机选择的，并且$y_j-x_j\in\{0,1\}$对于每个坐标$j$，那么概率至少是$\delta$$x$和$y$都属于$A$。对于$\ell>2$，有充分条件。本文运用了加性组合学和噪声敏感性理论的技术，以一种新颖而有趣的方式将两者结合起来。它还包含几个有趣的开放问题。

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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.