有限生成群直积的一个几何模拟定理

IF 1 3区 数学 Q1 MATHEMATICS Discrete Analysis Pub Date : 2017-06-02 DOI:10.19086/da.8820
S. Barbieri
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Wang believed that every tiling should be periodic, but his student Robert Berger showed in his PhD thesis in 1964 that the the tiling problem could be used to encode the halting problem, thereby proving that there was no algorithm for solving the former, which yielded the first known example of a set of tiles that could tile the plane but only aperiodically. (The result appeared in paper form in 1966.)\n\nThe notions of Wang tilings and aperiodicity have been fruitfully generalized from $\\mathbb Z^2$ to more general groups, as follows. Let $G$ be a group (which will be infinite) and let $\\mathcal A$ be a set of symbols, which we can think of as our \"tiles\". Define a _pattern_ to be a function $p:X\\to\\mathcal A$, where $X$ is some finite subset of $G$. Given a function $\\omega:G\\to\\mathcal A$, say that the pattern $p$ _occurs in_ $\\omega$ if there exists some $g\\in G$ such that $\\omega(gx)=p(x)$ for every $x\\in X$. Now let $P$ be a finite set of forbidden patterns. The set of all functions $\\omega$ such that no pattern $p\\in P$ occurs in $\\omega$ is called the _subshift of finite type_ determined by $P$. The functions $\\omega$ that satisfy this condition are called _configurations_. Note that the set of tilings of the plane with a given set of Wang tiles is a subshift of finite type determined by the rules that stipulate when two tiles may be placed next to each other, each of which is given by a forbidden pattern of size 2. \n\nNote that $G$ acts on a subshift of finite type in an obvious way: if $h\\in G$ and $\\omega$ is a configuration, then so is the function $\\omega_h$ defined by $\\omega_h(g)=\\omega(h^{-1}g)$. The map $(h,\\omega)\\mapsto\\omega_h$ is easily checked to be an action. The subshift is called _strongly aperiodic_ if this action is free: that is, if no non-trivial group element takes any configuration to itself. In the case of Wang tiles, the subshift is strongly aperiodic if and only if no tiling with the given set of tiles is periodic.\n\nThis paper is about so-called _simulation theorems_. A basic example of such a theorem is the following result mentioned by the authors. A group is said to be _recursively presented_ if it is countably generated and there is an algorithm for determining whether any given word in the generators is a relation. It is known that every subgroup of a finitely presented group is recursively presented, and a theorem of Graham Higman states the converse: that every recursively presented group can be embedded into a finitely presented group.\n\nThe interesting feature of this theorem is that a rather complicated object -- a recursively presented group -- can be embedded into a much simpler one -- a finitely presented group. In this paper, a theorem of a similar kind is proved for dynamical systems. It can be shown that if the shift action of a subshift of finite type is restricted to a subgroup, the resulting action need not be a subshift of finite type. However it has the important property of being _effectively closed_. This means, roughly speaking, that there is an algorithm that determines, for any group element $g$, any pair $\\omega,\\omega'$ of configurations, and any pair $N_1,N_2$ of basic open neighbourhoods of $\\omega_g$ and $\\omega'$ (in the product topology), whether $N_1$ and $N_2$ are disjoint. Even more roughly, it is effectively closed if there is an algorithm that allows one to approximate the action arbitrarily well.\n\nOne can now ask whether an effectively closed subshift can be embedded, in a suitable sense, into a subshift of finite type. The main result of this paper is a result of exactly this type. It has a number of interesting consequences, of which a notable one is that the Grigorchuk group (the famous group that exhibits growth that is intermediate between polynomial and exponential) admits a non-empty strongly aperiodic subshift of finite type. The proof builds on a number of deep ideas due to Mike Hochman and Tom Meyerovitch, and the author and Mathieu Sablik. An unusual feature of the argument is that it obtains aperiodic tilings by first obtaining computational simulations, rather than first obtaining aperiodic tilings and then extracting computational corollaries from them.","PeriodicalId":37312,"journal":{"name":"Discrete Analysis","volume":null,"pages":null},"PeriodicalIF":1.0000,"publicationDate":"2017-06-02","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"10","resultStr":"{\"title\":\"A geometric simulation theorem on direct products of finitely generated groups\",\"authors\":\"S. Barbieri\",\"doi\":\"10.19086/da.8820\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"A geometric simulation theorem on direct products of finitely generated groups, Discrete Analysis 2019:9, 25 pp.\\n\\nIn 1961, the mathematician and philosopher Hao Wang introduced the notion that we now call a _Wang tiling_ of $\\\\mathbb Z^2$. Each tile is a unit square with edges marked in a certain way, and two tiles can be placed next to each other if and only if the adjacent edges have the same marking. (Also, tiles are not allowed to be rotated.) \\n\\nWang observed that if every set of Wang tiles admits a periodic tiling, then there is an algorithm for deciding whether any given finite set of Wang tiles can tile the plane, since if it cannot, then by an easy compactness argument there is some finite subset of the plane that cannot be tiled, whereas if it can, then one can do a brute-force search for a fundamental domain of the tiling. Wang believed that every tiling should be periodic, but his student Robert Berger showed in his PhD thesis in 1964 that the the tiling problem could be used to encode the halting problem, thereby proving that there was no algorithm for solving the former, which yielded the first known example of a set of tiles that could tile the plane but only aperiodically. (The result appeared in paper form in 1966.)\\n\\nThe notions of Wang tilings and aperiodicity have been fruitfully generalized from $\\\\mathbb Z^2$ to more general groups, as follows. Let $G$ be a group (which will be infinite) and let $\\\\mathcal A$ be a set of symbols, which we can think of as our \\\"tiles\\\". Define a _pattern_ to be a function $p:X\\\\to\\\\mathcal A$, where $X$ is some finite subset of $G$. Given a function $\\\\omega:G\\\\to\\\\mathcal A$, say that the pattern $p$ _occurs in_ $\\\\omega$ if there exists some $g\\\\in G$ such that $\\\\omega(gx)=p(x)$ for every $x\\\\in X$. 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引用次数: 10

摘要

有限生成群的直积几何模拟定理,《离散分析》,2019:9,25页。1961年,数学家、哲学家王昊提出了我们现在称之为$\mathbb Z^2$的_Wang tiling_的概念。每个瓷砖都是一个单位正方形,其边缘以一定的方式标记,当且仅当相邻的边缘具有相同的标记时,两个瓷砖可以相邻放置。(另外,不允许旋转贴图。)Wang观察到,如果每一组Wang瓷砖允许周期性的平铺,那么就有一种算法来决定是否任何给定的有限的Wang瓷砖可以平铺平面,因为如果它不能,那么通过一个简单的紧性论证,平面的一些有限子集不能平铺,而如果它可以,那么就可以做一个蛮力搜索平铺的基本域。王认为,每一个平铺应该是周期性的,但他的学生罗伯特·伯格在1964年的博士论文中表明,平铺问题可以用来编码停止问题,从而证明没有算法来解决前者,这产生了一组瓦片的第一个例子,可以平铺平面,但只是非周期性的。(结果于1966年以论文形式发表。)Wang tilings和非周期的概念已经成功地从$\mathbb Z^2$推广到更一般的群,如下所示。设$G$是一个群(它将是无限的),设$\mathcal $ a $是一组符号,我们可以把它们想象成我们的“瓷砖”。定义_pattern_为函数$p:X\to\mathcal a $,其中$X$是$G$的某个有限子集。给定一个函数$\omega:G\to\mathcal a$,如果在G$中存在一些$ G\使得$\omega(gx)=p(x)$对于x $中的每一个$x\,则模式$p$ _出现在$ $\omega$中。现在设P是一个被禁止模式的有限集合。使得p $中没有模式$p $出现在$ $中所有函数的集合称为由$p $决定的有限类型的_子移位。满足此条件的函数称为_configuration_。请注意,平面上的一组给定的Wang牌是有限类型的子移位,该子移位由规定两个牌何时可以相邻放置的规则决定,每个牌由大小为2的禁止模式给出。注意,$G$以一种明显的方式作用于有限类型的子位移:如果$h\在G$和$\omega$中是一个构型,那么由$\omega_h(G)=\omega(h^{-1} G)$定义的函数$\omega_h$也是一个构型。map $(h,\omega)\mapsto\omega_h$很容易被检查为一个动作。如果子移位是自由的,则子移位称为_强非周期_,也就是说,如果没有非平凡的群元素为其本身取任何配置。在Wang贴图的情况下,子位移是强非周期性的当且仅当给定贴图集合的所有贴图都是周期性的。本文是关于所谓的“模拟定理”。这个定理的一个基本例子是作者提到的下面的结果。如果一个组是可数生成的,并且存在一种算法来确定生成器中的任何给定单词是否为关系,则称其为递归呈现的。已知有限表示群的每一个子群都是递归表示的,而Graham Higman的一个定理则相反:每一个递归表示群都可以嵌入到有限表示群中。这个定理的有趣之处在于,一个相当复杂的对象——递归呈现的群——可以嵌入到一个简单得多的对象——有限呈现的群中。本文证明了动力系统的一类类似定理。可以证明,如果有限型子位移的位移作用被限制在一个子群上,则所得到的位移作用不一定是有限型的子位移。然而,它具有有效封闭的重要性质。这意味着,粗略地说,有一种算法可以确定,对于任意群元素$g$,任意组态$\omega,\omega'$对,以及$\omega_g$和$\omega'$的基本开邻域$N_1,N_2$对(在积拓扑中),$N_1$和$N_2$是否不相交。更粗略地说,如果有一种算法允许人们任意地近似动作,那么它就是有效关闭的。现在我们可以问,在适当的意义上,一个有效闭合的子位移是否可以嵌入到一个有限类型的子位移中。本文的主要结果正是这种类型的结果。它有许多有趣的结果,其中一个值得注意的是Grigorchuk群(表现出介于多项式和指数之间的增长的著名群)允许有限型的非空强非周期子移。这个证明建立在Mike Hochman和Tom Meyerovitch以及作者和Mathieu Sablik提出的一些深刻想法的基础上。 该论点的一个不同寻常的特点是,它通过首先获得计算模拟来获得非周期平铺,而不是首先获得非周期平铺,然后从中提取计算推论。
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A geometric simulation theorem on direct products of finitely generated groups
A geometric simulation theorem on direct products of finitely generated groups, Discrete Analysis 2019:9, 25 pp. In 1961, the mathematician and philosopher Hao Wang introduced the notion that we now call a _Wang tiling_ of $\mathbb Z^2$. Each tile is a unit square with edges marked in a certain way, and two tiles can be placed next to each other if and only if the adjacent edges have the same marking. (Also, tiles are not allowed to be rotated.) Wang observed that if every set of Wang tiles admits a periodic tiling, then there is an algorithm for deciding whether any given finite set of Wang tiles can tile the plane, since if it cannot, then by an easy compactness argument there is some finite subset of the plane that cannot be tiled, whereas if it can, then one can do a brute-force search for a fundamental domain of the tiling. Wang believed that every tiling should be periodic, but his student Robert Berger showed in his PhD thesis in 1964 that the the tiling problem could be used to encode the halting problem, thereby proving that there was no algorithm for solving the former, which yielded the first known example of a set of tiles that could tile the plane but only aperiodically. (The result appeared in paper form in 1966.) The notions of Wang tilings and aperiodicity have been fruitfully generalized from $\mathbb Z^2$ to more general groups, as follows. Let $G$ be a group (which will be infinite) and let $\mathcal A$ be a set of symbols, which we can think of as our "tiles". Define a _pattern_ to be a function $p:X\to\mathcal A$, where $X$ is some finite subset of $G$. Given a function $\omega:G\to\mathcal A$, say that the pattern $p$ _occurs in_ $\omega$ if there exists some $g\in G$ such that $\omega(gx)=p(x)$ for every $x\in X$. Now let $P$ be a finite set of forbidden patterns. The set of all functions $\omega$ such that no pattern $p\in P$ occurs in $\omega$ is called the _subshift of finite type_ determined by $P$. The functions $\omega$ that satisfy this condition are called _configurations_. Note that the set of tilings of the plane with a given set of Wang tiles is a subshift of finite type determined by the rules that stipulate when two tiles may be placed next to each other, each of which is given by a forbidden pattern of size 2. Note that $G$ acts on a subshift of finite type in an obvious way: if $h\in G$ and $\omega$ is a configuration, then so is the function $\omega_h$ defined by $\omega_h(g)=\omega(h^{-1}g)$. The map $(h,\omega)\mapsto\omega_h$ is easily checked to be an action. The subshift is called _strongly aperiodic_ if this action is free: that is, if no non-trivial group element takes any configuration to itself. In the case of Wang tiles, the subshift is strongly aperiodic if and only if no tiling with the given set of tiles is periodic. This paper is about so-called _simulation theorems_. A basic example of such a theorem is the following result mentioned by the authors. A group is said to be _recursively presented_ if it is countably generated and there is an algorithm for determining whether any given word in the generators is a relation. It is known that every subgroup of a finitely presented group is recursively presented, and a theorem of Graham Higman states the converse: that every recursively presented group can be embedded into a finitely presented group. The interesting feature of this theorem is that a rather complicated object -- a recursively presented group -- can be embedded into a much simpler one -- a finitely presented group. In this paper, a theorem of a similar kind is proved for dynamical systems. It can be shown that if the shift action of a subshift of finite type is restricted to a subgroup, the resulting action need not be a subshift of finite type. However it has the important property of being _effectively closed_. This means, roughly speaking, that there is an algorithm that determines, for any group element $g$, any pair $\omega,\omega'$ of configurations, and any pair $N_1,N_2$ of basic open neighbourhoods of $\omega_g$ and $\omega'$ (in the product topology), whether $N_1$ and $N_2$ are disjoint. Even more roughly, it is effectively closed if there is an algorithm that allows one to approximate the action arbitrarily well. One can now ask whether an effectively closed subshift can be embedded, in a suitable sense, into a subshift of finite type. The main result of this paper is a result of exactly this type. It has a number of interesting consequences, of which a notable one is that the Grigorchuk group (the famous group that exhibits growth that is intermediate between polynomial and exponential) admits a non-empty strongly aperiodic subshift of finite type. The proof builds on a number of deep ideas due to Mike Hochman and Tom Meyerovitch, and the author and Mathieu Sablik. An unusual feature of the argument is that it obtains aperiodic tilings by first obtaining computational simulations, rather than first obtaining aperiodic tilings and then extracting computational corollaries from them.
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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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