Ball characterizations in planes and spaces of constant curvature, II .1cm This pdf-file is not identical with the printed paper.
Abstract
High proved the following theorem. If the intersections of any two congruent copies of a plane convex body are centrally symmetric, then this body is a circle. In our paper we extend the theorem of High to the sphere and the hyperbolic plane, and partly to spaces of constant curvature. We also investigate the dual question about the convex hull of the unions, rather than the intersections. Let us have in H2 proper closed convex subsets K,L with interior points, such that the numbers of the connected components of the boundaries of K and L are finite. We exactly describe all pairs of such subsets K,L, whose any congruent copies have an intersection with axial symmetry; there are nine cases. (The cases of S2 and R2 were described in Part I, i.e., 5.) Let us have in Sd, Rd or Hd proper closed convex C2+ subsets K,L with interior points, such that all sufficiently small intersections of their congruent copies are symmetric w.r.t.\ a particular hyperplane. Then the boundary components of both K and L are congruent, and each of them is a sphere, a parasphere or a hypersphere. Let us have a pair of convex bodies in Sd, Rd or Hd, which have at any boundary points supporting spheres (for Sd of radius less than π /2). If the convex hull of the union of any congruent copies of these bodies is centrally symmetric, then our bodies are congruent balls (for Sd of radius less than π /2). An analogous statement holds for symmetry w.r.t.\ a particular hyperplane. For d=2, suppose the existence of the above supporting circles (for S2 of radius less than π /2), and, for S2, smoothness of K and L. If we suppose axial symmetry of all the above convex hulls, then our bodies are (incongruent) circles (for S2 of radii less than π /2).
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