Quad Mesh Quantization Without a T‐Mesh

Coudert‐Osmont, Yoann; Desobry, David; Heistermann, Martin; Bommes, David; Ray, Nicolas; Sokolov, Dmitry

doi:10.1111/cgf.14928

Computer Graphics Forum

2023

DOI: 10.1111/cgf.14928

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Quad Mesh Quantization Without a T‐Mesh

Yoann Coudert‐Osmont,

David Desobry,

Martin Heistermann

et al.

Abstract: Grid preserving maps of triangulated surfaces were introduced for quad meshing because the 2D unit grid in such maps corresponds to a sub‐division of the surface into quad‐shaped charts. These maps can be obtained by solving a mixed integer optimization problem: Real variables define the geometry of the charts and integer variables define the combinatorial structure of the decomposition. To make this optimization problem tractable, a common strategy is to ignore integer constraints at first, then to enforce th… Show more

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Cited by 2 publications

References 29 publications

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AMRTO: Automated CAD model reconstruction of topology optimization result

Ren,

Xia,

Wang

et al. 2025

Computer Methods in Applied Mechanics and Engineering

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AMRTO: Automated CAD model reconstruction of topology optimization result

Ren,

Xia,

Wang

et al. 2025

Computer Methods in Applied Mechanics and Engineering

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Integer‐Sheet‐Pump Quantization for Hexahedral Meshing

Brückler,

Bommes,

Campen

2024

Computer Graphics Forum

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Several state‐of‐the‐art algorithms for semi‐structured hexahedral meshing involve a so called quantization step to decide on the integer DoFs of the meshing problem, corresponding to the number of hexahedral elements to embed into certain regions of the domain. Existing reliable methods for quantization are based on solving a sequence of integer quadratic programs (IQP). Solving these in a timely and predictable manner with general‐purpose solvers is a challenge, even more so in the open‐source field. We present here an alternative robust and efficient quantization scheme that is instead based on solving a series of continuous linear programs (LP), for which solver availability and efficiency are not an issue. In our formulation, such LPs are used to determine where inflation or deflation of virtual hexahedral sheets are favorable. We compare our method to two implementations of the former IQP formulation (using a commercial and an open‐source MIP solver, respectively), finding that (a) the solutions found by our method are near‐optimal or optimal in most cases, (b) these solutions are found within a much more predictable time frame, and (c) the state of the art run time is outperformed, in the case of using the open‐source solver by orders of magnitude.

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Quad Mesh Quantization Without a T‐Mesh

Cited by 2 publications

References 29 publications

AMRTO: Automated CAD model reconstruction of topology optimization result

AMRTO: Automated CAD model reconstruction of topology optimization result

Integer‐Sheet‐Pump Quantization for Hexahedral Meshing

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