Improved packing of equal circles on a sphere and rigidity of its graph

Abstract: How must n equal non-overlapping circles be packed on a sphere so that the angular diameter of the circles will be as great as possible? In the paper, the conjectured solutions of this problem for n = 18, 27, 34, 35, 40 are improved on the basis of an idea of Danzer. Using the theory of bar structures it is ascertained that, in these cases, the edge-length of the graphs of the circle-packings can be increased till, in the graphs, additional edges appear which prevent further motions apart from rigid motions. T… Show more

“…In this paper we use the same terms and relationships of the theory of bar structures as in [27]. For the sake of convenience of the reader we present the most important ones here also.…”

“…The edges of the graph of a covering by circles do not intersect [21]. Therefore, due to proposition (5l) of [27] the graph of a covering of the sphere by circles cannot be infinitesimally rigid. If the graph can have a state of self-stress, then the graph is rigid, that is, has no finite free motion (but still has infinitesimal free motion).…”

“…Let us denote this submatrix by G. The properties of matrix G are identical to that of the compatibility matrix of structures belonging to class (iii). Therefore, for G, the statements in §4 (iii) of [27] are valid, but instead of an increase, a decrease of temperature should be taken into account. After executing the abovementioned modification in (3) we can determine ds.…”

“…As mentioned in the Introduction the problem of packing n equal circles on a spherical surface and the problem of covering a sphere by n equal circles are dual counterparts of each other. This is also expressed by the fact that for the packing problem a heating algorithm [27], while for the covering problem a cooling algorithm can be used. For packing we have the modified Robinson conjecture [31]: CONJECTURE 1.…”

“…The graph of a covering of the sphere by circles may be considered theoretically as a cable net, but it turns out in practice to be more convenient to investigate a net of bars instead. Thus, on the analogy with spherical circle packings [27] the graph of a covering is modelled as a structure consisting of straight bars and frictionless pin joints (of types (A) and (B)) sliding on the surface of the sphere of a fixed diameter; and in the analysis the theory of bar structures [24] is applied. Change in length of the bars is attributed to a change in 'temperature'.…”

Covering a sphere by equal circles, and the rigidity of its graph

“…In this paper we use the same terms and relationships of the theory of bar structures as in [27]. For the sake of convenience of the reader we present the most important ones here also.…”

“…The edges of the graph of a covering by circles do not intersect [21]. Therefore, due to proposition (5l) of [27] the graph of a covering of the sphere by circles cannot be infinitesimally rigid. If the graph can have a state of self-stress, then the graph is rigid, that is, has no finite free motion (but still has infinitesimal free motion).…”

“…Let us denote this submatrix by G. The properties of matrix G are identical to that of the compatibility matrix of structures belonging to class (iii). Therefore, for G, the statements in §4 (iii) of [27] are valid, but instead of an increase, a decrease of temperature should be taken into account. After executing the abovementioned modification in (3) we can determine ds.…”

“…As mentioned in the Introduction the problem of packing n equal circles on a spherical surface and the problem of covering a sphere by n equal circles are dual counterparts of each other. This is also expressed by the fact that for the packing problem a heating algorithm [27], while for the covering problem a cooling algorithm can be used. For packing we have the modified Robinson conjecture [31]: CONJECTURE 1.…”

“…The graph of a covering of the sphere by circles may be considered theoretically as a cable net, but it turns out in practice to be more convenient to investigate a net of bars instead. Thus, on the analogy with spherical circle packings [27] the graph of a covering is modelled as a structure consisting of straight bars and frictionless pin joints (of types (A) and (B)) sliding on the surface of the sphere of a fixed diameter; and in the analysis the theory of bar structures [24] is applied. Change in length of the bars is attributed to a change in 'temperature'.…”

Covering a sphere by equal circles, and the rigidity of its graph

Application of Maxeler DataFlow Supercomputing to Spherical Code Design

Configuration Spaces of Equal Spheres Touching a Given Sphere: The Twelve Spheres Problem