STRUCTURE OF DETERMINATIVE SUBSPACE IN TRIANGULAR CELL SPACE : INFORMATION SCIENCE APPROACH TO BIOMATHEMATICS, VIII

Bulletin of Mathematical Statistics Pub Date : 1971-03-01 DOI:10.5109/13056

M. Yamaguchi

{"title":"STRUCTURE OF DETERMINATIVE SUBSPACE IN TRIANGULAR CELL SPACE : INFORMATION SCIENCE APPROACH TO BIOMATHEMATICS, VIII","authors":"M. Yamaguchi","doi":"10.5109/13056","DOIUrl":null,"url":null,"abstract":"The notion of stable configuration in a Sn' cell space which is invariant under any application of local majority transformation (LMT) was introduced in Kitagawa and Yamaguchi [1] and the notion of determinative subspace in a 4(71) cell space which determines a structure of a stable configuration was introduced in our paper [2]. Some structual properties of determinative subspace in ZI(n) cell space were suggested throughout various examples of determinative subspace in Kitagawa and Yamaguchi [3]. According to the definitions of generative and non-generative determinative subspace in 4(n) cell space given by Kitagawa [4] in view of propagation of determined cells, these examples are mostly concerned with those of generative determinative subspace in 4(n) cell space. The purpose of this paper is to give a deeper investigation for the constructions of determinative subspaces in 4(n) cell space. In SECTION 2 we shall introduce several notions which are indispensable for a construction procedure of generative determinative subspace in 4(m) cell space such as a convex set, a spiny convex set and a two-cell extension of a set and so on. In SECTION 3 we shall give a certain type of construction procedure of any generative determinative subspace in zl(n) cell space. In APPENDIX we shall give an example of our construction process of a generative determinative subspace obtained by using this proceduce. In SECTION 4 we shall introduce several notions of elementary subsets and superposition of elementary subsets and decomposition of the whole cell space into a family of superposed elementary subsets. These nations are fundamental tools for proving THEOREM 3 and 4, which give us a construction procedure and hence a structural characteristic feature of any non-generative determinative subspace in 4(n) cell space. The last SECTION 5 is devoted to the another proof of THEOREM 2 in our previours paper [2] which appeals to LEMMA 4 in the present paper prepared for giving our construction procedure of non-generative determinative determinative","PeriodicalId":287765,"journal":{"name":"Bulletin of Mathematical Statistics","volume":"20 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"1971-03-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"2","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Bulletin of Mathematical Statistics","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.5109/13056","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 2

Abstract

The notion of stable configuration in a Sn' cell space which is invariant under any application of local majority transformation (LMT) was introduced in Kitagawa and Yamaguchi [1] and the notion of determinative subspace in a 4(71) cell space which determines a structure of a stable configuration was introduced in our paper [2]. Some structual properties of determinative subspace in ZI(n) cell space were suggested throughout various examples of determinative subspace in Kitagawa and Yamaguchi [3]. According to the definitions of generative and non-generative determinative subspace in 4(n) cell space given by Kitagawa [4] in view of propagation of determined cells, these examples are mostly concerned with those of generative determinative subspace in 4(n) cell space. The purpose of this paper is to give a deeper investigation for the constructions of determinative subspaces in 4(n) cell space. In SECTION 2 we shall introduce several notions which are indispensable for a construction procedure of generative determinative subspace in 4(m) cell space such as a convex set, a spiny convex set and a two-cell extension of a set and so on. In SECTION 3 we shall give a certain type of construction procedure of any generative determinative subspace in zl(n) cell space. In APPENDIX we shall give an example of our construction process of a generative determinative subspace obtained by using this proceduce. In SECTION 4 we shall introduce several notions of elementary subsets and superposition of elementary subsets and decomposition of the whole cell space into a family of superposed elementary subsets. These nations are fundamental tools for proving THEOREM 3 and 4, which give us a construction procedure and hence a structural characteristic feature of any non-generative determinative subspace in 4(n) cell space. The last SECTION 5 is devoted to the another proof of THEOREM 2 in our previours paper [2] which appeals to LEMMA 4 in the present paper prepared for giving our construction procedure of non-generative determinative determinative

查看原文本刊更多论文

三角形细胞空间中确定子空间的结构:生物数学的信息科学方法，8

在Kitagawa和Yamaguchi[1]中引入了Sn单元空间中稳定位形的概念，它在任何局部多数变换(local majority transformation, LMT)的应用下都是不变的。在我们的论文[2]中引入了4(71)单元空间中确定稳定位形结构的确定子空间的概念。通过Kitagawa和Yamaguchi[3]中的各种确定子空间的例子，提出了ZI(n)单元空间中确定子空间的一些结构性质。根据Kitagawa[4]针对确定细胞的繁殖给出的4(n)细胞空间中生成和非生成的确定子空间的定义，这些例子主要涉及4(n)细胞空间中生成确定子空间的定义。本文的目的是对4(n)元空间中确定子空间的构造进行更深入的研究。在第二节中，我们将介绍在4(m)元空间中生成确定子空间的构造过程中不可缺少的几个概念，如凸集、刺凸集和集合的两元扩展等。在第3节中，我们将给出zl(n)单元空间中任意生成确定子空间的一类构造过程。在附录中，我们将给出一个用这个方法得到的生成式确定子空间的构造过程的例子。在第4节中，我们将介绍基本子集和基本子集的叠加以及将整个细胞空间分解为叠加的基本子集族的几个概念。这些国家是证明定理3和定理4的基本工具，定理3和定理4给了我们一个构造过程，从而给出了4(n)单元空间中任何非生成确定子空间的结构特征特征。最后的第5节是我们以前的论文[2]中定理2的另一个证明，它引用了本文中为给出非生成行列式的构造过程而准备的引理4

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Bulletin of Mathematical Statistics

自引率

0.00%

发文量