Tetrahedral mesh improvement by shell transformation

Existing flips for tetrahedral meshes simply make a selection from a few possible configurations within a single shell (i.e., a polyhedron that can be filled up with a mesh composed of a set of elements that meet each other at one edge), and their effectiveness is usually confined. A new topological...

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Bibliographic Details
Published in:Engineering with computers 2017-07, Vol.33 (3), p.393-414
Main Authors: Chen, Jianjun, Zheng, Jianjing, Zheng, Yao, Xiao, Zhoufang, Si, Hang, Yao, Yufeng
Format: Article
Language:English
Subjects:
Algorithms
CAE) and Design
Calculus of Variations and Optimal Control
Optimization
Classical Mechanics
Computational efficiency
Computer Science
Computer-Aided Engineering (CAD
Computing time
Control
Math. Applications in Chemistry
Mathematical and Computational Engineering
Original Article
Systems Theory
Topology
Transformations
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Summary:Existing flips for tetrahedral meshes simply make a selection from a few possible configurations within a single shell (i.e., a polyhedron that can be filled up with a mesh composed of a set of elements that meet each other at one edge), and their effectiveness is usually confined. A new topological operation for tetrahedral meshes named shell transformation is proposed. Its recursive callings execute a sequence of shell transformations on neighboring shells, acting like composite edge removal transformations. Such topological transformations are able to perform on a much larger element set than that of a single flip, thereby leading the way towards a better local optimum solution. Hence, a new mesh improvement algorithm is developed by combining this recursive scheme with other schemes, including smoothing, point insertion, and point suppression. Numerical experiments reveal that the proposed algorithm can well balance some stringent and yet sometimes even conflict requirements of mesh improvement, i.e., resulting in high-quality meshes and reducing computing time at the same time. Therefore, it can be used for mesh quality improvement tasks involving millions of elements, in which it is essential not only to generate high-quality meshes, but also to reduce total computational time for mesh improvement.
ISSN:0177-0667
1435-5663
DOI:10.1007/s00366-016-0480-z