距离两个给定几何图形等距离的点的几何位置。第4部分:距离两个球体等远点的几何位置

Vladimir Vyshnyepolskiy, E. Zavarihina, D. Peh
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引用次数: 6

摘要

本文讨论了两个球体等距点的几何位置。在球体相互位置的所有变体中,点的几何位置是两个表面。当球体的中心与距球体等距离的点的轨迹重合时,将会有等于原球体直径的一半和一半差的球体。在初始球体相对位置的三种变体中,点的几何位置的两个表面之一是两片旋转双曲面。当:(1)球体相交,(2)球体接触,(3)球体的外表面彼此远离时,可以得到它。在等球的情况下,两片旋转双曲面退化为两片平面,更准确地说,它是一个二阶退化曲面,具有无限远的第二个分支。两个球体相交,点的第二个轨迹将是旋转椭球。球体接触——第二个点轨迹——一个旋转椭球体,退化成一条直线,更准确地说,退化成二阶零二次曲面——一个半径为零的圆柱面。球体的外表面彼此相距很远——第二个点轨迹将是一个两片的旋转双曲面。小球体位于大的一、二同轴共焦旋转椭球内。在相同直径的球体相互位置的所有变体中,等距点的共同几何位置是一个平面(二阶简并面),穿过垂直于它的线段的中间,连接原始球体的中心。与两个直径相同的球体等距的第二个点轨迹可以是一个旋转椭球(如果原始球体相交),或者当原始球体相互接触时连接原始球体中心的直线(半径为零的圆柱面),或者是一个两片旋转双曲面(如果继续增加原始球体中心之间的距离)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Geometric Locations of Points Equally Distance from Two Given Geometric Figures. Part 4: Geometric Locations of Points Equally Remote from Two Spheres
The article deals with the geometric locations of points equidistant from two spheres. In all variants of the mutual position of the spheres, the geometric places of the points are two surfaces. When the centers of the spheres coincide with the locus of points equidistant from the spheres, there will be spheres equal to the half-sum and half-difference of the diameters of the original spheres. In three variants of the relative position of the initial spheres, one of the two surfaces of the geometric places of the points is a two-sheet hyperboloid of revolution. It is obtained when: 1) the spheres intersect, 2) the spheres touch, 3) the outer surfaces of the spheres are removed from each other. In the case of equal spheres, a two-sheeted hyperboloid of revolution degenerates into a two-sheeted plane, more precisely, it is a second-order degenerate surface with a second infinitely distant branch. The spheres intersect - the second locus of the points will be the ellipsoid of revolution. Spheres touch - the second locus of points - an ellipsoid of revolution, degenerated into a straight line, more precisely into a zero-quadric of the second order - a cylindrical surface with zero radius. The outer surfaces of the spheres are distant from each other - the second locus of points will be a two-sheet hyperboloid of revolution. The small sphere is located inside the large one - two coaxial confocal ellipsoids of revolution. In all variants of the mutual position of spheres of the same diameters, the common geometrical place of equidistant points is a plane (degenerate surface of the second order) passing through the middle of the segment perpendicular to it, connecting the centers of the original spheres. The second locus of points equidistant from two spheres of the same diameter can be either an ellipsoid of revolution (if the original spheres intersect), or a straight (cylindrical surface with zero radius) connecting the centers of the original spheres when the original spheres touch each other, or a two-sheet hyperboloid of revolution (if continue to increase the distance between the centers of the original spheres).
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