Multi-material adaptive volume remesher

Noura Faraj; Jean Marc Thiery; Tamy Boubekeur

doi:10.1016/j.cag.2016.05.019

Multi-material adaptive volume remesher

Noura Faraj, Jean Marc Thiery, Tamy Boubekeur

CNRS LTCI

Research output: Contribution to journal › Article › peer-review

Abstract

We propose a practical iterative remeshing algorithm for multi-material tetrahedral meshes which is solely based on simple local topological operations, such as edge collapse, flip, split and vertex smoothing. To do so, we exploit an intermediate implicit feature complex which reconstructs piecewise smooth multi-material boundaries made of surface patches, feature edges and corner vertices. Furthermore, we design specific feature-aware local remeshing rules which, combined with a moving least square projection, result in high quality isotropic meshes representing the input mesh at a user defined resolution while preserving important features. Our algorithm uses only topology-aware local operations, which allows us to process difficult input meshes such as self-intersecting ones. We evaluate our approach on a collection of examples and experimentally show that it is fast and scales well.

Original language	English
Pages (from-to)	150-160
Number of pages	11
Journal	Computers and Graphics (Pergamon)
Volume	58
DOIs	https://doi.org/10.1016/j.cag.2016.05.019
Publication status	Published - 1 Aug 2016
Externally published	Yes

Keywords

Feature preservation
Multi-material tetrahedral mesh
Volume remeshing

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10.1016/j.cag.2016.05.019

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title = "Multi-material adaptive volume remesher",

abstract = "We propose a practical iterative remeshing algorithm for multi-material tetrahedral meshes which is solely based on simple local topological operations, such as edge collapse, flip, split and vertex smoothing. To do so, we exploit an intermediate implicit feature complex which reconstructs piecewise smooth multi-material boundaries made of surface patches, feature edges and corner vertices. Furthermore, we design specific feature-aware local remeshing rules which, combined with a moving least square projection, result in high quality isotropic meshes representing the input mesh at a user defined resolution while preserving important features. Our algorithm uses only topology-aware local operations, which allows us to process difficult input meshes such as self-intersecting ones. We evaluate our approach on a collection of examples and experimentally show that it is fast and scales well.",

keywords = "Feature preservation, Multi-material tetrahedral mesh, Volume remeshing",

author = "Noura Faraj and Thiery, \{Jean Marc\} and Tamy Boubekeur",

note = "Publisher Copyright: {\textcopyright} 2016 Elsevier Ltd.",

year = "2016",

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doi = "10.1016/j.cag.2016.05.019",

language = "English",

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AU - Thiery, Jean Marc

AU - Boubekeur, Tamy

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N2 - We propose a practical iterative remeshing algorithm for multi-material tetrahedral meshes which is solely based on simple local topological operations, such as edge collapse, flip, split and vertex smoothing. To do so, we exploit an intermediate implicit feature complex which reconstructs piecewise smooth multi-material boundaries made of surface patches, feature edges and corner vertices. Furthermore, we design specific feature-aware local remeshing rules which, combined with a moving least square projection, result in high quality isotropic meshes representing the input mesh at a user defined resolution while preserving important features. Our algorithm uses only topology-aware local operations, which allows us to process difficult input meshes such as self-intersecting ones. We evaluate our approach on a collection of examples and experimentally show that it is fast and scales well.

AB - We propose a practical iterative remeshing algorithm for multi-material tetrahedral meshes which is solely based on simple local topological operations, such as edge collapse, flip, split and vertex smoothing. To do so, we exploit an intermediate implicit feature complex which reconstructs piecewise smooth multi-material boundaries made of surface patches, feature edges and corner vertices. Furthermore, we design specific feature-aware local remeshing rules which, combined with a moving least square projection, result in high quality isotropic meshes representing the input mesh at a user defined resolution while preserving important features. Our algorithm uses only topology-aware local operations, which allows us to process difficult input meshes such as self-intersecting ones. We evaluate our approach on a collection of examples and experimentally show that it is fast and scales well.

KW - Feature preservation

KW - Multi-material tetrahedral mesh

KW - Volume remeshing

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DO - 10.1016/j.cag.2016.05.019

M3 - Article

AN - SCOPUS:84973495077

SN - 0097-8493

VL - 58

SP - 150

EP - 160

JO - Computers and Graphics (Pergamon)

JF - Computers and Graphics (Pergamon)

ER -

Multi-material adaptive volume remesher

Abstract

Keywords

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