Geometria Complessa e Geometria Differenziale
Geometria Complessa e Geometria Differenziale
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M. Longinetti - S. Naldi

On the configurations of four spheres supporting the vertices of a tetrahedron

created by naldi on 05 Jun 2024

[BibTeX]

preprint

Inserted: 5 jun 2024
Last Updated: 5 jun 2024

Year: 2024

ArXiv: 2405.16167 PDF

Abstract:

A reformulation of the three circles theorem of Johnson with distance coordinates to the vertices of a triangle is explicitly represented in a polynomial system and solved by symbolic computation. A similar polynomial system in distance coordinates to the vertices of a tetrahedron $T \subset \mathbb{R}^3$ is introduced to represent the configurations of four spheres of radius $R^*$, which intersect in one point, each sphere containing three vertices of $T$ but not the fourth one. This problem is related to that of computing the largest value $r$ for which the set of vertices of $T$ is an $r$-body. For triangular pyramids we completely describe the set of geometric configurations with the required four balls of radius $R^*$. The solutions obtained by symbolic computation show that triangular pyramids are splitted into two different classes: in the first one $R^*$ is unique, in the second one three values $R^*$ there exist. The first class can be itself subdivided into two subclasses, one of which is related to the family of $r$-bodies.

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