Open AccessParallel Mesh Adaptive Techniques for Complex Flow Simulation: Geometry Conservation
Author(s) -
Angelo Casagrande,
Pénélope Leyland,
Luca Formaggia
Publication year - 2012
Publication title -
modelling and simulation in engineering
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.264
H-Index - 20
eISSN - 1687-5591
pISSN - 1687-5605
DOI - 10.1155/2012/495935
Subject(s) - computer science , complex geometry , projection (relational algebra) , cad , boundary (topology) , computational science , mesh generation , computer aided design , adaptation (eye) , process (computing) , flow (mathematics) , geometry , adaptive mesh refinement , computational geometry , topology (electrical circuits) , algorithm , engineering drawing , finite element method , engineering , mathematics , structural engineering , physics , electrical engineering , mathematical analysis , optics , operating system
Dynamic mesh adaptation on unstructured grids, by localised refinement and derefinement, is a very efficient tool for enhancing solution accuracy and optimising computational time. One of the major drawbacks, however, resides in the projection of the new nodes created, during the refinement process, onto the boundary surfaces. This can be addressed by the introduction of a library capable of handling geometric properties given by a CAD (computer-aided design) description. This is of particular interest also to enhance the adaptation module when the mesh is being smoothed, and hence moved, to then reproject it onto the surface of the exact geometry
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