The geometric element transformation method (GETMe) is an efficient geometry driven approach to mesh smoothing. It is based on regularizing element transformations which, if applied iteratively to a single element, improve its regularity and with this its quality. The smoothing method has already successfully been applied in the case of mixed surface meshes as well as all-tetrahedral and all-hexahedral meshes. In this paper, a GETMe-based approach for smoothing mixed volume meshes is presented. For this purpose, dual element-based regularizing transformations for tetrahedral, hexahedral, pyramidal, and prismatic elements are introduced and analyzed. Furthermore, it is shown that the general concept of GETMe smoothing also applies to mixed volume meshes requiring only minor modifications. Numerical results demonstrate that high quality meshes comparable to those obtained by a state of the art global optimization-based approach can be achieved within significantly shorter runtimes.
Computer Methods in Applied Mechanics and Engineering
number
0
pages
65--81
volume
201-204
urldate
2011-12-15
issn
0045-7825
file
ScienceDirect Full Text PDF:C:\Users\hessenauer\AppData\Roaming\Mozilla\Firefox\Profiles\1h9szxht.firefox4\zotero\storage\GM388EWZ\Vartziotis und Wipper - 2012 - Fast smoothing of mixed volume meshes based on the.pdf:application/pdf;ScienceDirect Snapshot:C:\Users\hessenauer\AppData\Roaming\Mozilla\Firefox\Profiles\1h9szxht.firefox4\zotero\storage\DF2TJEIF\Vartziotis und Wipper - 2012 - Fast smoothing of mixed volume meshes based on the:
%0 Journal Article
%1 vartziotis_fast_2012
%A Vartziotis, Dimitris
%A Wipper, Joachim
%D 2012
%J Computer Methods in Applied Mechanics and Engineering
%K Finite Hybrid Mesh Mixed element mesh mesh, quality, smoothing, {GETMe},
%N 0
%P 65--81
%R 10.1016/j.cma.2011.09.008
%T Fast smoothing of mixed volume meshes based on the effective geometric element transformation method
%U http://www.sciencedirect.com/science/article/pii/S0045782511002970
%V 201-204
%X The geometric element transformation method (GETMe) is an efficient geometry driven approach to mesh smoothing. It is based on regularizing element transformations which, if applied iteratively to a single element, improve its regularity and with this its quality. The smoothing method has already successfully been applied in the case of mixed surface meshes as well as all-tetrahedral and all-hexahedral meshes. In this paper, a GETMe-based approach for smoothing mixed volume meshes is presented. For this purpose, dual element-based regularizing transformations for tetrahedral, hexahedral, pyramidal, and prismatic elements are introduced and analyzed. Furthermore, it is shown that the general concept of GETMe smoothing also applies to mixed volume meshes requiring only minor modifications. Numerical results demonstrate that high quality meshes comparable to those obtained by a state of the art global optimization-based approach can be achieved within significantly shorter runtimes.
@article{vartziotis_fast_2012,
abstract = {The geometric element transformation method ({GETMe)} is an efficient geometry driven approach to mesh smoothing. It is based on regularizing element transformations which, if applied iteratively to a single element, improve its regularity and with this its quality. The smoothing method has already successfully been applied in the case of mixed surface meshes as well as all-tetrahedral and all-hexahedral meshes. In this paper, a {GETMe-based} approach for smoothing mixed volume meshes is presented. For this purpose, dual element-based regularizing transformations for tetrahedral, hexahedral, pyramidal, and prismatic elements are introduced and analyzed. Furthermore, it is shown that the general concept of {GETMe} smoothing also applies to mixed volume meshes requiring only minor modifications. Numerical results demonstrate that high quality meshes comparable to those obtained by a state of the art global optimization-based approach can be achieved within significantly shorter runtimes.},
added-at = {2013-01-26T11:35:39.000+0100},
author = {Vartziotis, Dimitris and Wipper, Joachim},
biburl = {https://www.bibsonomy.org/bibtex/219209e55be3d3ed73eed1ec8e5fad29d/bhessen},
doi = {10.1016/j.cma.2011.09.008},
file = {ScienceDirect Full Text PDF:C:\Users\hessenauer\AppData\Roaming\Mozilla\Firefox\Profiles\1h9szxht.firefox4\zotero\storage\GM388EWZ\Vartziotis und Wipper - 2012 - Fast smoothing of mixed volume meshes based on the.pdf:application/pdf;ScienceDirect Snapshot:C:\Users\hessenauer\AppData\Roaming\Mozilla\Firefox\Profiles\1h9szxht.firefox4\zotero\storage\DF2TJEIF\Vartziotis und Wipper - 2012 - Fast smoothing of mixed volume meshes based on the:},
interhash = {895c5df9d5fa9f68a8d85d4d79c4dd38},
intrahash = {19209e55be3d3ed73eed1ec8e5fad29d},
issn = {0045-7825},
journal = {Computer Methods in Applied Mechanics and Engineering},
keywords = {Finite Hybrid Mesh Mixed element mesh mesh, quality, smoothing, {GETMe},},
month = jan,
number = 0,
pages = {65--81},
timestamp = {2013-01-26T11:35:39.000+0100},
title = {Fast smoothing of mixed volume meshes based on the effective geometric element transformation method},
url = {http://www.sciencedirect.com/science/article/pii/S0045782511002970},
urldate = {2011-12-15},
volume = {201-204},
year = 2012
}