English

Algebraic Representations for Volumetric Frame Fields

Graphics 2020-04-29 v2

Abstract

Field-guided parametrization methods have proven effective for quad meshing of surfaces; these methods compute smooth cross fields to guide the meshing process and then integrate the fields to construct a discrete mesh. A key challenge in extending these methods to three dimensions, however, is representation of field values. Whereas cross fields can be represented by tangent vector fields that form a linear space, the 3D analog---an octahedral frame field---takes values in a nonlinear manifold. In this work, we describe the space of octahedral frames in the language of differential and algebraic geometry. With this understanding, we develop geometry-aware tools for optimization of octahedral fields, namely geodesic stepping and exact projection via semidefinite relaxation. Our algebraic approach not only provides an elegant and mathematically-sound description of the space of octahedral frames but also suggests a generalization to frames whose three axes scale independently, better capturing the singular behavior we expect to see in volumetric frame fields. These new odeco frames, so-called as they are represented by orthogonally decomposable tensors, also admit a semidefinite program--based projection operator. Our description of the spaces of octahedral and odeco frames suggests computing frame fields via manifold-based optimization algorithms; we show that these algorithms efficiently produce high-quality fields while maintaining stability and smoothness.

Keywords

Cite

@article{arxiv.1908.05411,
  title  = {Algebraic Representations for Volumetric Frame Fields},
  author = {David Palmer and David Bommes and Justin Solomon},
  journal= {arXiv preprint arXiv:1908.05411},
  year   = {2020}
}

Comments

17 pages, 20 figures

R2 v1 2026-06-23T10:47:59.446Z