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Main Authors: Couplet, Mattéo, Chemin, Alexandre, Bommes, David, Chien, Edward
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.03889
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author Couplet, Mattéo
Chemin, Alexandre
Bommes, David
Chien, Edward
author_facet Couplet, Mattéo
Chemin, Alexandre
Bommes, David
Chien, Edward
contents We present a method for generating orthogonal quadrilateral meshes subject to user-defined feature alignment and sizing constraints. The approach relies on computing integrable orthogonal frame fields, whose symmetries are implicitly represented using orthogonally decomposable (odeco) tensors. We extend the existing 2D odeco integrability formulation to the 3D setting, and define the useful energies in a finite element approach. Our frame fields are shear-free (orthogonal) by construction, and we provide terms to minimize area and/or stretch distortion. The optimization naturally creates and places singularities to achieve integrability, obviating the need for user placement or greedy iterative methods. We validate the method on both smooth surfaces and feature-rich CAD models. Compared to previous works on integrable frame fields, we offer better performance in the presence of mesh sizing constraints and achieve lower distortion metrics.
format Preprint
id arxiv_https___arxiv_org_abs_2604_03889
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Surface Quadrilateral Meshing from Integrable Odeco Fields
Couplet, Mattéo
Chemin, Alexandre
Bommes, David
Chien, Edward
Computational Geometry
We present a method for generating orthogonal quadrilateral meshes subject to user-defined feature alignment and sizing constraints. The approach relies on computing integrable orthogonal frame fields, whose symmetries are implicitly represented using orthogonally decomposable (odeco) tensors. We extend the existing 2D odeco integrability formulation to the 3D setting, and define the useful energies in a finite element approach. Our frame fields are shear-free (orthogonal) by construction, and we provide terms to minimize area and/or stretch distortion. The optimization naturally creates and places singularities to achieve integrability, obviating the need for user placement or greedy iterative methods. We validate the method on both smooth surfaces and feature-rich CAD models. Compared to previous works on integrable frame fields, we offer better performance in the presence of mesh sizing constraints and achieve lower distortion metrics.
title Surface Quadrilateral Meshing from Integrable Odeco Fields
topic Computational Geometry
url https://arxiv.org/abs/2604.03889