Litcius/Paper detail

Orienting point clouds with dipole propagation

Gal Metzer, Rana Hanocka, Denis Zorin, Raja Giryes, Daniele Panozzo, Daniel Cohen‐Or

2021ACM Transactions on Graphics60 citationsDOIOpen Access PDF

Abstract

Establishing a consistent normal orientation for point clouds is a notoriously difficult problem in geometry processing, requiring attention to both local and global shape characteristics. The normal direction of a point is a function of the local surface neighborhood; yet, point clouds do not disclose the full underlying surface structure. Even assuming known geodesic proximity, calculating a consistent normal orientation requires the global context. In this work, we introduce a novel approach for establishing a globally consistent normal orientation for point clouds. Our solution separates the local and global components into two different sub-problems. In the local phase, we train a neural network to learn a coherent normal direction per patch ( i.e. , consistently oriented normals within a single patch). In the global phase, we propagate the orientation across all coherent patches using a dipole propagation. Our dipole propagation decides to orient each patch using the electric field defined by all previously orientated patches. This gives rise to a global propagation that is stable, as well as being robust to nearby surfaces, holes, sharp features and noise.

Topics & Concepts

Point cloudPoint (geometry)Computer scienceDipolePhysicsGeometryArtificial intelligenceMathematicsQuantum mechanics3D Shape Modeling and AnalysisAdvanced Numerical Analysis TechniquesComputational Geometry and Mesh Generation