On the number of points in general position in the plane

IF 1 3区 数学 Q1 MATHEMATICS
Discrete Analysis Pub Date : 2017-04-17 DOI:10.19086/da.4438
J. Balogh, J. Solymosi
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引用次数: 22

Abstract

On the number of points in general position in the plane, Discrete Analysis 2018:16, 20 pp. A recurring theme in combinatorics is questions of the following kind. Suppose that we have a combinatorial structure $S$ of size $n$ that contains no object of type $A$. Then how large a subset of $S$ can we find that contains no object of type $B$? For example, a graph with $n$ vertices that contains no clique of size 4 can be shown quite easily to have a triangle-free subgraph with $n^{1/2}$ vertices, and Wolfovitz has shown that there are graphs with no clique of size 4 and no triangle-free subgraph with more than $n^{1/2}(\log n)^{120}$ vertices. One of the main questions discussed in this paper is perhaps the first question of this type one would think of in discrete geometry: if $S$ is a set of $n$ points in the plane and if no four of these points are collinear, then how large a subset of $S$ can one find with no three collinear? A bound of $o(n)$ follows from the density Hales-Jewett theorem, which implies that a subset of $\{1,2,3\}^k$ of positive density contains three points in a line. It is not hard to project the set $\{1,2,3\}$ into the plane in such a way that collinearity is preserved, but no four points of the image lie in a line. However, the bound obtained this way is very weak -- roughly $n/\log_*(n)$. This paper obtains the first reasonable bound for the problem, namely $n^{5/6+o(1)}$. It is not clear whether 5/6 is the right exponent, but the authors suggest that their construction may be close to optimal and that the difficulty is to calculate the correct exponent for that example. Perhaps the most interesting aspect of the paper is that it uses the so-called method of containers. This method, developed by Saxton and Thomason, and independently by Balogh, Morris and Samotij, has already been used to solve a large number of important problems, but this appears to be the first time it has been used to solve a problem in discrete geometry, and it is used in a novel way. They also use containers to prove a second discrete geometry result, this time about epsilon-nets. Given a family $\mathcal F$ of subsets of a finite set $X$, an $\epsilon$-net $E$ of $\mathcal F$ is a subset $E$ of $X$ such that every $F\in\mathcal F$ of size at least $\epsilon|X|$ contains an element of $E$. There are many interesting questions about the sizes of $\epsilon$-nets when $X$ is a geometrical set such as a finite set of points in the plane, and $\mathcal F$ is some natural class of subsets such as the set of all intersections of $X$ with convex bodies. With this example, one can also define a _weak_ $\epsilon$-net as follows: it is a set of points $E$ in the plane, not necessarily a subset of $X$, such that every convex hull of at least $\epsilon|X|$ points of $X$ contains a point of $E$. Natural notions of weak $\epsilon$-nets can be defined in many other contexts too. An interesting open question, asked by Noga Alon, is whether there is some natural geometrically defined family $\mathbb F$ of bounded VC-dimension such that the smallest $\epsilon$-net has size at least $(c/\epsilon)\log(1/\epsilon)$. Also using the density Hales-Jewett theorem, Alon obtained a bound that was very slightly superlinear in the case where $X$ was a certain point set and $\mathcal F$ was the set of all intersections of lines with $X$. In this paper, Alon's bound is improved to $(1/\epsilon)\log(1/\epsilon)^{1/3-o(1)}$, which is much closer to the bound he suggests might be obtainable. They also obtain an improved bound for weak $\epsilon$-nets, but with a power of $\log\log(1/\epsilon)$ replacing the power of $\log(1/\epsilon)$. This construction has the additional feature that it works just as well in the projective plane.
平面上一般位置上的点的个数
关于平面中一般位置的点的数量,离散分析2018:16,20页。组合数学中一个反复出现的主题是以下类型的问题。假设我们有一个大小为$n$的组合结构$S$,它不包含类型为$a$的对象。那么,我们能找到多大的$S$子集不包含$B$类型的对象?例如,具有$n$个顶点且不包含大小为4的团的图可以很容易地显示为具有$n^{1/2}$个顶点的无三角形子图,并且Wolfovitz已经表明,存在不具有大小为4个团的图,并且不具有顶点超过$n^{1/2}(\log n)^{120}$的无三角子图。本文讨论的主要问题之一可能是离散几何中人们会想到的第一个此类问题:如果$S$是平面上的一组$n$点,如果这些点中没有四个共线,那么在没有三个共线的情况下,人们能找到多大的$S$子集?密度Hales-Jewett定理给出了$o(n)$的界,这意味着正密度的$\{1,2,3\}^k$的子集在一条线上包含三个点。不难将集合$\{1,2,3\}$投影到平面中,这样可以保持共线,但图像的四个点都不在一条线上。然而,通过这种方式获得的界是非常弱的——大约是$n/\log_*(n)$。本文得到了该问题的第一个合理界,即$n^{5/6+o(1)}$。目前尚不清楚5/6是否是正确的指数,但作者认为,他们的构造可能接近最优,困难在于计算该示例的正确指数。也许这篇论文最有趣的方面是它使用了所谓的容器方法。这种方法由Saxton和Thomason开发,Balogh、Morris和Samotij独立开发,已经被用于解决大量重要问题,但这似乎是它首次被用于解决离散几何中的问题,并且以一种新颖的方式使用。他们还使用容器来证明第二个离散几何结果,这次是关于ε网的。给定有限集$X$的子集的族$\mathcalF$,$\mathcal F$的$\epsilon$-net$E$是$X$中的子集$E$,使得大小至少为$\eptilon|X|$的每个$F\in\mathcal F都包含$E$的元素。当$X$是一个几何集,例如平面上的有限点集,并且$\mathcal F$是一些自然的子集类,例如$X$与凸体的所有交集的集时,关于$\epsilon$-网的大小有很多有趣的问题。在这个例子中,还可以定义_weak_$\epsilon$-net如下:它是平面上的一组点$E$,而不一定是$X$的子集,因此$X$中至少$\epsilon |X|$个点的每个凸包都包含一个$E$的点。弱$\epsilon$-nets的自然概念也可以在许多其他上下文中定义。Noga Alon提出的一个有趣的开放问题是,是否存在一些自然几何定义的有界VC维的族$\mathbb F$,使得最小的$\epsilon$-net的大小至少为$(c/\epsilon)\log(1/\epsilon$)。同样使用密度Hales-Jewett定理,Alon得到了一个在$X$是某个点集并且$\mathcal F$是线与$X$的所有交点的集合的情况下非常轻微超线性的界。在本文中,Alon的界被改进为$(1/\epsilon)\log(1/\epilon)^{1/3-o(1)}$,这与他提出的可能获得的界更接近。他们还获得了弱$\epsilon$-网的改进界,但用$\log\log(1/\epsilon$)$的幂代替了$\log(1\\epsilon$$)的幂。这种构造还有一个额外的特点,那就是它在投影平面上也能很好地工作。
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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来源期刊
Discrete Analysis
Discrete Analysis Mathematics-Algebra and Number Theory
CiteScore
1.60
自引率
0.00%
发文量
1
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.
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