Let P be a locally finite disk pattern on the complex plane C whose
combinatorics are described by the one-skeleton G of a triangulation of the
open topological disk and whose dihedral angles are equal to a function
\Theta:E\to [0,\pi/2] on the set of edges. Let P^* be a combinatorially
equivalent disk pattern on the plane with the same dihedral angle function. We
show that P and P^* differ only by a euclidean similarity.
In particular, when the dihedral angle function \Theta is identically zero,
this yields the rigidity theorems of B. Rodin and D. Sullivan, and of O.
Schramm, whose arguments rely essentially on the pairwise disjointness of the
interiors of the disks. The approach here is analytical, and uses the maximum
principle, the concept of vertex extremal length, and the recurrency of a
family of electrical networks obtained by placing resistors on the edges in the
contact graph of the pattern.
A similar rigidity property holds for locally finite disk patterns in the
hyperbolic plane, where the proof follows by a simple use of the maximum
principle. Also, we have a uniformization result for disk patterns.
In a future paper, the techniques of this paper will be extended to the case
when 0 \le \Theta < \pi. In particular, we will show a rigidity property for a
class of infinite convex polyhedra in the 3-dimensional hyperbolic space.Comment: 33 pages, published versio