A characterization of the sphere in terms of the stereographic projection

Abstract

Let K be a convex body in the 3-dimensional Euclidian space E3 and let N,S in the boubdary bdK of K, N=S. Suppose that the support plane S of K at S is unique. For every point x in bd K, different than N, we define the stereographic projection :bdK \N\ → S of x onto S as the point y:=L(N,x) S. It is a well known property of the sphere S2 in E3 that the stereographic projection maps circles onto circles (see Hilbert pag. 248). In this work we investigate what geometric elements determines that this property is fulfilled. Here we demonstrate that the following two properties of a convex body K⊂ E3 in terms of the stereographic projection characterize the sphere in E3: (1) The cones defined by the sections of K and the point N are axially symmetric (that is, they are invariant under a rotation by an angle of π). (2) given a section K of K, the rotation that leaves the cone defined by K and N invariant is such that it maps K into a homothetic figure to (K) by a homothety with center of homothety at N. An important element in the proof of the main theorem of this work is a cha\-racterization of the circle based on a geometric property, which will be called the stereographic property. It is worth highlighting that the stereographic projection defined on the sphere maps circles onto circles is intimately linked to the conditions (1) and (2) and the stereographic property of the circle.