复平面上的圆

A. Girsh
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引用次数: 4

摘要

欧几里得平面和欧几里得空间本身在定义上并不包含虚元,而是通过特殊的情况与它们不可分割地联系在一起,这就导致需要将几何传播到虚值的区域中。这样的传播,也就是将一个平面或空间,一个虚坐标场加到实坐标场中,根据给定的公理,会导致不同维度空间的各种变体。之前,在一些论文中,展示了使用虚几何像解决一些紧迫的几何问题的例子[2,9,11,13,15]。本文研究复平面上圆的正交位置和圆的直径位置的构造。在复空间中一个球与四个给定球正交的命题上,推广了复平面上一个圆与三个给定球正交的命题。研究表明,圆在欧几里德e平面上的直径位置是圆虚分量在伪欧几里德m平面上的正交位置的一个属性。本文讨论了实圆、虚圆和退化为点圆的结构,论证了这些圆的形式、性质和正交位置的性质。给出了同类型圆和不同类型圆的根轴和根心的构造方法。给出了二维圆在三维球面上相互正交位置的传播。在图形中,虚线表示虚元素。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Circles on the Complex Plane
The Euclidean plane and Euclidean space themselves do not contain imaginary elements by definition, but are inextricably linked with them through special cases, and this leads to the need to propagate geometry into the area of imaginary values. Such propagation, that is adding a plane or space, a field of imaginary coordinates to the field of real coordinates leads to various variants of spaces of different dimensions, depending on the given axiomatics. Earlier, in a number of papers, were shown examples for solving some urgent problems of geometry using imaginary geometric images [2, 9, 11, 13, 15]. In this paper are considered constructions of orthogonal and diametrical positions of circles on a complex plane. A generalization has been made of the proposition about a circle on the complex plane orthogonally intersecting three given spheres on the proposition about a sphere in the complex space orthogonally intersecting four given spheres. Studies have shown that the diametrical position of circles on the Euclidean E-plane is an attribute of the orthogonal position of the circles’ imaginary components on the pseudo-Euclidean M-plane. Real, imaginary and degenerated to a point circles have been involved in structures and considered, have been demonstrated these circles’ forms, properties and attributes of their orthogonal position. Has been presented the construction of radical axes and a radical center for circles of the same and different types. A propagation of 2D mutual orthogonal position of circles on 3D spheres has been made. In figures, dashed lines indicate imaginary elements.
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