Constant mean curvature surfaces from ring patterns: Geometry from combinatorics

TL;DR

This paper introduces a combinatorial approach to constructing discrete constant mean curvature surfaces using sphere packings and ring patterns, connecting geometry, variational principles, and classical surface theory.

Contribution

It defines discrete cmc surfaces via sphere packings with orthogonal circles, linking combinatorics to classical surface theory and extending minimal surface models.

Findings

Discrete cmc surfaces constructed from orthogonal ring patterns.

Variational principle enables solving boundary value problems.

Limit cases recover discrete minimal surfaces related to Koebe polyhedra.

Abstract

We define discrete constant mean curvature (cmc) surfaces in the three-dimensional Euclidean and Lorentz spaces in terms of sphere packings with orthogonally intersecting circles. These discrete cmc surfaces can be constructed from orthogonal ring patterns in the two-sphere and the hyperbolic plane. We present a variational principle that allows us to solve boundary value problems and to construct discrete analogues of some classical cmc surfaces. The data used for the construction is purely combinatorial - the combinatorics of the curvature line pattern. In the limit of orthogonal circle patterns we recover the theory of discrete minimal surfaces associated to Koebe polyhedra all edges of which touch a sphere. These are generalized to two-sphere Koebe nets, i.e., nets with planar quadrilateral faces and edges that alternately touch two concentric spheres.