{"title":"Sets, groups, and fields definable in vector spaces with a bilinear form","authors":"J. Dobrowolski","doi":"10.5802/aif.3559","DOIUrl":null,"url":null,"abstract":"We study definable sets, groups, and fields in the theory $T_\\infty$ of infinite-dimensional vector spaces over an algebraically closed field equipped with a nondegenerate symmetric (or alternating) bilinear form. First, we define an ($\\mathbb{N}\\times \\mathbb{Z},\\leq_{lex}$)-valued dimension on definable sets in $T_\\infty$ enjoying many properties of Morley rank in strongly minimal theories. Then, using this dimension notion as the main tool, we prove that all groups definable in $T_\\infty$ are (algebraic-by-abelian)-by-algebraic, which, in particular, answers a question of Granger. We conclude that every infinite field definable in $T_\\infty$ is definably isomorphic to the field of scalars of the vector space. We derive some other consequences of good behaviour of the dimension in $T_\\infty$, e.g. every generic type in any definable set is a definable type; every set is an extension base; every definable group has a definable connected component. \nWe also consider the theory $T^{RCF}_\\infty$ of vector spaces over a real closed field equipped with a nondegenerate alternating bilinear form or a nondegenerate symmetric positive-definite bilinear form. Using the same construction as in the case of $T_\\infty$, we define a dimension on sets definable in $T^{RCF}_\\infty$, and using it we prove analogous results about definable groups and fields: every group definable in $T^{RCF}_{\\infty}$ is (semialgebraic-by-abelian)-by-semialgebraic (in particular, it is (Lie-by-abelian)-by-Lie), and every field definable in $T^{RCF}_{\\infty}$ is definable in the field of scalars, hence it is either real closed or algebraically closed.","PeriodicalId":50781,"journal":{"name":"Annales De L Institut Fourier","volume":" ","pages":""},"PeriodicalIF":0.8000,"publicationDate":"2020-04-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"8","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Annales De L Institut Fourier","FirstCategoryId":"100","ListUrlMain":"https://doi.org/10.5802/aif.3559","RegionNum":4,"RegionCategory":"数学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"MATHEMATICS","Score":null,"Total":0}
引用次数: 8
Abstract
We study definable sets, groups, and fields in the theory $T_\infty$ of infinite-dimensional vector spaces over an algebraically closed field equipped with a nondegenerate symmetric (or alternating) bilinear form. First, we define an ($\mathbb{N}\times \mathbb{Z},\leq_{lex}$)-valued dimension on definable sets in $T_\infty$ enjoying many properties of Morley rank in strongly minimal theories. Then, using this dimension notion as the main tool, we prove that all groups definable in $T_\infty$ are (algebraic-by-abelian)-by-algebraic, which, in particular, answers a question of Granger. We conclude that every infinite field definable in $T_\infty$ is definably isomorphic to the field of scalars of the vector space. We derive some other consequences of good behaviour of the dimension in $T_\infty$, e.g. every generic type in any definable set is a definable type; every set is an extension base; every definable group has a definable connected component.
We also consider the theory $T^{RCF}_\infty$ of vector spaces over a real closed field equipped with a nondegenerate alternating bilinear form or a nondegenerate symmetric positive-definite bilinear form. Using the same construction as in the case of $T_\infty$, we define a dimension on sets definable in $T^{RCF}_\infty$, and using it we prove analogous results about definable groups and fields: every group definable in $T^{RCF}_{\infty}$ is (semialgebraic-by-abelian)-by-semialgebraic (in particular, it is (Lie-by-abelian)-by-Lie), and every field definable in $T^{RCF}_{\infty}$ is definable in the field of scalars, hence it is either real closed or algebraically closed.
我们研究了具有非退化对称(或交替)双线性形式的代数闭域上无穷维向量空间的理论$T_\infty$中的可定义集、群和域。然后,用这个维概念作为主要工具,我们证明了在$T_infty$中可定义的所有群都是(阿贝尔代数的)-by-代数的,这特别回答了Granger的一个问题。我们得出结论,在$T_infty$中可定义的每个无限域都可定义同构于向量空间的标量域。我们导出了$T_\infty$中维度的良好行为的一些其他结果,例如,任何可定义集合中的每个泛型类型都是可定义类型;每个集合都是一个可拓基;每个可定义的群都有一个可定义的连通分量。我们还考虑了$T理论^{RCF}_\实闭域上具有非退化交替双线性形式或非退化对称正定双线性形式的向量空间的infty$。使用与$T_\infty$情况相同的构造,我们在$T中可定义的集合上定义了一个维数^{RCF}_\infty$,并用它证明了关于可定义群和域的类似结果:在$T中可定义的每个群^{RCF}_{\infty}$is(semialgebraic by abelian)-by-semialgebraic(特别是,它是(Lie by abelian)-by-Lie),并且$T中可定义的每个域^{RCF}_{\fty}$在标量域中是可定义的,因此它要么是实闭的,要么是代数闭的。
期刊介绍:
The Annales de l’Institut Fourier aim at publishing original papers of a high level in all fields of mathematics, either in English or in French.
The Editorial Board encourages submission of articles containing an original and important result, or presenting a new proof of a central result in a domain of mathematics. Also, the Annales de l’Institut Fourier being a general purpose journal, highly specialized articles can only be accepted if their exposition makes them accessible to a larger audience.