在黄金分割和黄金矩形的基础上构建二十面体、十二面体和阿基米德固体

В. Васильева, V. Vasil’eva
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引用次数: 7

摘要

本文简要介绍了正多面体理论的发展历史。该工作向读者介绍了两个最复杂的正多面体的建模-柏拉图固体:二十面体和十二面体,在AutoCAD软件包。建议以二十面体的黄金矩形为基础,像黄金分割一样,采用边比矩形的二十面体和十二面体建筑方法。这种方法是众所周知的,用于二十面体,但很少应用于十二面体,因为在现有的文献中,建议将后者构建为二十面体的图形对偶。这项工作提供了意大利数学家L. Pacioli在他的《神圣比例》一书中第一次提到这种建筑方法的信息。1937年,苏联数学家D.I. Perepelkin发表了一篇关于正二十面体和正十二面体的一种建筑情况的论文,他指出这种“方法不是很为人所知”,并提供了一个“完全基于分割黄金分割比例的截距”的建筑。考虑到基于黄金矩形的建筑的简单性和良好的可视化,本文对正六面体内嵌的二十面体和十二面体进行了计算机建模。鉴于此,如果我们用黄金分割的概念来思考,矩形的大边等于正六面体的整个截距边,而二十面体和十二面体矩形的小边则被计算为黄金分割比的一部分(分别是大部分和小部分)。演示了如何使用这些多面体的对偶连接的线框图像方案作为基础,计算黄金分割比中的矩形的边,以构建这些对偶图形的“无限”级联,以及构建围绕正六面体的二十面体和十二面体。基于黄金分割矩形的方法也适用于构建半正多面体——阿基米德固体:截断二十面体、截断十二面体、二十十二面体、菱形十二面体、菱形二十十二面体,这些都是基于二十面体和十二面体。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Golden Section and Golden Rectangles When Building Icosahedron, Dodecahedron and Archimedean Solids Based On Them
A brief history of the development of the regular polyhedrons theory is given. The work introduces the reader to modelling of the two most complex regular polyhedrons – Platonic solids: icosahedron and dodecahedron, in AutoCAD package. It is suggested to apply the method of the icosahedron and dodecahedron building using rectangles with their sides’ ratio like in the golden section, having taken the icosahedron’s golden rectangles as a basis. This method is well-known-of and is used for icosahedron, but is extremely rarely applied to dodecahedron, as in the available literature it is suggested to build the latter one as a figure dual to icosahedron. The work provides information on the first mentioning of this building method by an Italian mathematician L. Pacioli in his Divine Proportion book. In 1937, a Soviet mathematician D.I. Perepelkin published a paper On One Building Case of the Regular Icosahedron and Regular Dodecahedron, where he noted that this “method is not very well known of” and provided a building based “solely on dividing an intercept in the golden section ratio”. Taking into account the simplicity and good visualization of the building based on golden rectangles, a computer modeling of icosahedron and dodecahedron inscribed in a regular hexahedron is performed in the article. Given that, if we think in terms of the golden section concepts, the bigger side of the rectangle equals a whole intercept – side of the regular hexahedron, and the smaller sides of the icosahedron and dodecahedron rectangles are calculated as parts of the golden section ratio (of the bigger part and the smaller one, respectively). It is demonstrated how, using the scheme of a wireframe image of the dual connection of these polyhedrons as a basis, to calculate the sides of the rectangles in the golden section ratio in order to build an “infinite” cascade of these dual figures, as well as to build the icosahedron and dodecahedron circumscribed about the regular hexahedron. The method based on using the golden-section rectangles is also applied to building semiregular polyhedrons – Archimedean solids: a truncated icosahedron, truncated dodecahedron, icosidodecahedron, rhombicosidodecahedron, and rhombitruncated icosidodecahedron, which are based on icosahedron and dodecahedron.
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