Discrete Geodesic Nets for Modeling Developable Surfaces

TL;DR

This paper introduces a simple, local discrete model for developable surfaces using quadrilateral meshes and angle constraints, enabling independent deformation and isometric interpolation.

Contribution

It proposes a novel discrete theory based on orthogonal geodesics that models developable surfaces without directly encoding rulings, allowing flexible surface editing.

Findings

Model aligns closely with smooth developable surfaces, satisfying constraints up to second order.

Enables local definition of discrete isometry for developable surfaces.

Demonstrates effective surface editing and isometric interpolation in experiments.

Abstract

We present a discrete theory for modeling developable surfaces as quadrilateral meshes satisfying simple angle constraints. The basis of our model is a lesser known characterization of developable surfaces as manifolds that can be parameterized through orthogonal geodesics. Our model is simple, local, and, unlike previous works, it does not directly encode the surface rulings. This allows us to model continuous deformations of discrete developable surfaces independently of their decomposition into torsal and planar patches or the surface topology. We prove and experimentally demonstrate strong ties to smooth developable surfaces, including a theorem stating that every sampling of the smooth counterpart satisfies our constraints up to second order. We further present an extension of our model that enables a local definition of discrete isometry. We demonstrate the effectiveness of our discrete model in a developable surface editing system, as well as computation of an isometric interpolation between isometric discrete developable shapes.