Litcius/Paper detail

HodgeNet

Dmitriy Smirnov, Justin Solomon

2021ACM Transactions on Graphics57 citationsDOIOpen Access PDF

Abstract

Constrained by the limitations of learning toolkits engineered for other applications, such as those in image processing, many mesh-based learning algorithms employ data flows that would be atypical from the perspective of conventional geometry processing. As an alternative, we present a technique for learning from meshes built from standard geometry processing modules and operations. We show that low-order eigenvalue/eigenvector computation from operators parameterized using discrete exterior calculus is amenable to efficient approximate backpropagation, yielding spectral per-element or per-mesh features with similar formulas to classical descriptors like the heat/wave kernel signatures. Our model uses few parameters, generalizes to high-resolution meshes, and exhibits performance and time complexity on par with past work.

Topics & Concepts

Polygon meshParameterized complexityComputer scienceComputationEigenvalues and eigenvectorsGeometry processingKernel (algebra)AlgorithmImage processingTheoretical computer scienceComputational scienceApplied mathematicsMathematical optimizationArtificial intelligenceMathematicsImage (mathematics)Computer graphics (images)Discrete mathematicsPhysicsQuantum mechanics3D Shape Modeling and AnalysisComputer Graphics and Visualization TechniquesComputational Geometry and Mesh Generation
HodgeNet | Litcius