A UNIFIED APPROACH TO HINDMAN, RAMSEY, AND VAN DER WAERDEN SPACES

The Journal of Symbolic Logic Pub Date : 2024-02-12 DOI:10.1017/jsl.2024.8

RAFAŁ FILIPÓW, KRZYSZTOF KOWITZ, ADAM KWELA

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Abstract

For many years, there have been conducting research (e.g., by Bergelson, Furstenberg, Kojman, Kubiś, Shelah, Szeptycki, Weiss) into sequentially compact spaces that are, in a sense, topological counterparts of some combinatorial theorems, for instance, Ramsey’s theorem for coloring graphs, Hindman’s finite sums theorem, and van der Waerden’s arithmetical progressions theorem. These spaces are defined with the aid of different kinds of convergences: IP-convergence, R-convergence, and ordinary convergence.

The first aim of this paper is to present a unified approach to these various types of convergences and spaces. Then, using this unified approach, we prove some general theorems about existence of the considered spaces and show that all results obtained so far in this subject can be derived from our theorems.

The second aim of this paper is to obtain new results about the specific types of these spaces. For instance, we construct a Hausdorff Hindman space that is not an Abstract Image $\mathcal {I}_{1/n}$-space and a Hausdorff differentially compact space that is not Hindman. Moreover, we compare Ramsey spaces with other types of spaces. For instance, we construct a Ramsey space that is not Hindman and a Hindman space that is not Ramsey.

The last aim of this paper is to provide a characterization that shows when there exists a space of one considered type that is not of the other kind. This characterization is expressed in purely combinatorial manner with the aid of the so-called Katětov order that has been extensively examined for many years so far.

This paper may interest the general audience of mathematicians as the results we obtain are on the intersection of topology, combinatorics, set theory, and number theory.

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亨德曼空间、拉姆齐空间和范德瓦登空间的统一方法

多年来，人们（如伯格森、弗斯滕贝格、科伊曼、库比希、谢拉赫、塞普茨基、魏斯等人）一直在研究序列紧凑空间，从某种意义上说，这些空间是一些组合定理的拓扑对应物，例如着色图的拉姆齐定理、辛德曼的有限和定理以及范德瓦登的算术级数定理。这些空间借助不同类型的收敛来定义：本文的首要目的是为这些不同类型的收敛和空间提出一种统一的方法。然后，利用这种统一的方法，我们证明了关于所考虑空间存在性的一些一般定理，并证明了迄今为止在这一课题中获得的所有结果都可以从我们的定理中推导出来。本文的第二个目的是获得关于这些空间特定类型的新结果。例如，我们构建了一个不是$\mathcal {I}_{1/n}$空间的Hausdorff Hindman空间，以及一个不是Hindman的Hausdorff Differentially compact空间。此外，我们还将拉姆齐空间与其他类型的空间进行了比较。本文的最后一个目的是提供一种特征描述，说明何时存在一种类型的空间而不是另一种类型的空间。本文以纯组合的方式表达了这一特征，并借助于迄今为止已被广泛研究多年的所谓卡捷托夫阶（Katětov order）。

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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The Journal of Symbolic Logic

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