Abstract
Field-guided parameterization 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.
Highlights
Inspired by the success of field-based approaches to quadrilateral meshing on surfaces, recent research in applied geometry has focused on developing an analogous approach to hexahedral meshing
Motivated by applications in finiteelement modeling, hexahedral meshing is the problem of dividing based optimization algorithms; we show that these algorithms efficiently a given volume into hexahedral elements with produce high-quality fields while maintaining stability and smoothness
Our description of the octahedral frame space as an algebraic variety suggests a different approach to projection based on semidefinite programming, which yields a certificate of global optimality in polynomial time
Summary
Inspired by the success of field-based approaches to quadrilateral meshing on surfaces (cf. Vaxman et al [2016]), recent research in applied geometry has focused on developing an analogous approach to hexahedral meshing. Our description of the octahedral frame space as an algebraic variety suggests a different approach to projection based on semidefinite programming, which yields a certificate of global optimality in polynomial time. Beyond precisely characterizing the space of octahedral frames, our algebraic approach admits a generalization to frames whose axes scale independently This larger space better captures frame field geometry—for example, allowing for a nonzero direction aligned to singular arcs even if the directions orthogonal to the arcs must vanish. A proof of isometric embedding of SO(3)/O in R9; descriptions of the spaces of octahedral and more general odeco frames as nested algebraic varieties; and new state-of-the-art optimization techniques for volumetric frame fields valued in both varieties, featuring geodesics and semidefinite program (SDP)-based projection as primitives
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