Nonlinear manifold learning for meshfree finite deformation thin-shell analysis

SUMMARY Calculations on general point‐set surfaces are attractive because of their flexibility and simplicity in the preprocessing but present important challenges. The absence of a mesh makes it nontrivial to decide if two neighboring points in the three‐dimensional embedding are nearby or rather f...

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Bibliographic Details
Published in:International journal for numerical methods in engineering Vol. 93; no. 7; pp. 685 - 713
Main Authors: Millán, Daniel, Rosolen, Adrian, Arroyo, Marino
Format: Journal Article Publication
Language:English
Published: Chichester, UK John Wiley & Sons, Ltd 17.02.2013
Wiley Subscription Services, Inc
John Wiley & Sons
Subjects:
74 Mechanics of deformable solids
74S Numerical methods
Anàlisi numèrica
Classificació AMS
Manifolds
Matemàtiques i estadística
Mathematical analysis
Mathematical models
maximum-entropy approximants
meshfree methods
Meshless methods
Mètodes numèrics
nonlinear dimensionality reduction
Nonlinearity
Numerical analysis
Numerical methods and algorithms
Parametrization
partition of unity
point-set surfaces
Resistència de materials
shells
Topology
Àrees temàtiques de la UPC
ISSN:0029-5981, 1097-0207
Online Access:Get full text
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Summary:SUMMARY Calculations on general point‐set surfaces are attractive because of their flexibility and simplicity in the preprocessing but present important challenges. The absence of a mesh makes it nontrivial to decide if two neighboring points in the three‐dimensional embedding are nearby or rather far apart on the manifold. Furthermore, the topology of surfaces is generally not that of an open two‐dimensional set, ruling out global parametrizations. We propose a general and simple numerical method analogous to the mathematical theory of manifolds, in which the point‐set surface is described by a set of overlapping charts forming a complete atlas. We proceed in four steps: (1) partitioning of the node set into subregions of trivial topology; (2) automatic detection of the geometric structure of the surface patches by nonlinear dimensionality reduction methods; (3) parametrization of the surface using smooth meshfree (here maximum‐entropy) approximants; and (4) gluing together the patch representations by means of a partition of unity. Each patch may be viewed as a meshfree macro‐element. We exemplify the generality, flexibility, and accuracy of the proposed approach by numerically approximating the geometrically nonlinear Kirchhoff–Love theory of thin‐shells. We analyze standard benchmark tests as well as point‐set surfaces of complex geometry and topology. Copyright © 2012 John Wiley & Sons, Ltd.
Bibliography:istex:3F0994DFDA90659E01859465EC041F76569A3F0E
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ISSN:0029-5981
1097-0207
DOI:10.1002/nme.4403