GravoTet

A fast multigrid hierarchy construction for tetrahedral meshes

Journal Article (2026)
Author(s)

Marcel Padilla (ETH Zürich)

Ruben Wiersma (ETH Zürich)

Tim Huisman (Student TU Delft)

Jackson Campolattaro (TU Delft - Electrical Engineering, Mathematics and Computer Science)

Olga Sorkine-Hornung (ETH Zürich)

Klaus Hildebrandt (TU Delft - Electrical Engineering, Mathematics and Computer Science)

Research Group
Computer Graphics and Visualisation
DOI related publication
https://doi.org/10.1016/j.cag.2026.104662 Final published version
More Info
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Publication Year
2026
Language
English
Research Group
Computer Graphics and Visualisation
Journal title
Computers and Graphics
Volume number
138
Article number
104662
Downloads counter
5
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Abstract

Geometric multigrid (GMG) methods are a fundamental tool for efficiently solving large sparse linear systems. A requirement for GMG is a hierarchy of grids; however, many practical volumetric domains are available only as single, irregular tetrahedral meshes, making the construction of a multigrid hierarchy necessary. Existing approaches often trade off speed against hierarchy quality: remeshing- or coarsening-based methods can be expensive to construct, whereas graph-based techniques are fast but often yield weaker multigrid performance. We introduce GravoTet, which bridges this gap by combining geometric structure with graph-based efficiency to construct fast and effective multigrid hierarchies. GravoTet builds a vertex hierarchy and then generates graph-Voronoi diagrams whose dual cells define coarse tetrahedra, enabling rapid construction of multigrid levels. Boundary elements are explicitly prioritized during both sampling and tet generation to preserve boundary. In our evaluation, we solve Poisson and biharmonic problems on irregular tetrahedral meshes and compare GravoTet against state-of-the-art geometric multigrid, algebraic multigrid and direct solvers, demonstrating superior performance, particularly on large meshes.