Optimization of a regularized distortion measure to generate curved high-order unstructured tetrahedral meshes

Summary We present a robust method for generating high‐order nodal tetrahedral curved meshes. The approach consists of modifying an initial linear mesh by first, introducing high‐order nodes, second, displacing the boundary nodes to ensure that they are on the computer‐aided design surface, and thir...

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Vydané v:	International journal for numerical methods in engineering Ročník 103; číslo 5; s. 342 - 363
Hlavní autori:	Gargallo-Peiró, A., Roca, X., Peraire, J., Sarrate, J.
Médium:	Journal Article Publikácia
Jazyk:	English
Vydavateľské údaje:	Bognor Regis Blackwell Publishing Ltd 03.08.2015 Wiley Subscription Services, Inc
Predmet:	90 Operations research, mathematical programming 90B Operations research and management science Algorithms Boundaries CAD Classificació AMS Curved curved meshing Displacement Distortion Investigació operativa Matemàtiques i estadística mesh generation mesh optimization mesh quality Operations research Optimització Optimization Preserves Smoothing unstructured high-order methods Àrees temàtiques de la UPC
ISSN:	0029-5981, 1097-0207, 1097-0207
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Shrnutí:	Summary We present a robust method for generating high‐order nodal tetrahedral curved meshes. The approach consists of modifying an initial linear mesh by first, introducing high‐order nodes, second, displacing the boundary nodes to ensure that they are on the computer‐aided design surface, and third, smoothing and untangling the mesh obtained after the displacement of the boundary nodes to produce a valid curved high‐order mesh. The smoothing algorithm is based on the optimization of a regularized measure of the mesh distortion relative to the original linear mesh. This means that whenever possible, the resulting mesh preserves the geometrical features of the initial linear mesh such as shape, stretching, and size. We present several examples to illustrate the performance of the proposed algorithm. Furthermore, the examples show that the implementation of the optimization problem is robust and capable of handling situations in which the mesh before optimization contains a large number of invalid elements. We consider cases with polynomial approximations up to degree ten, large deformations of the curved boundaries, concave boundaries, and highly stretched boundary layer elements. The meshes obtained are suitable for high‐order finite element analyses. Copyright © 2015 John Wiley & Sons, Ltd.
Bibliografia:	ark:/67375/WNG-XPQL77BZ-Z ArticleID:NME4888 istex:1C7241A4F15A23BF187A8BFB0C06B4C8B512F464 ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 14 content type line 23
ISSN:	0029-5981 1097-0207 1097-0207
DOI:	10.1002/nme.4888