This article describes a bridge between POD-based model order reduction
techniques and the classical Newton/Krylov solvers. This bridge is used to
derive an efficient algorithm to correct, "on-the-fly", the reduced order
modelling of highly nonlinear problems undergoing strong topological changes.
Damage initiation problems are addressed and tackle via a corrected
hyperreduction method. It is shown that the relevancy of reduced order model
can be significantly improved with reasonable additional costs when using this
algorithm, even when strong topological changes are involved

Allix

Bordas

Chinesta

Dostál

Feyel

Fish

Franceschini

Gosselet

Jefferson

Karhunen

Kerfriden

Ladevèze

Lemaître

Liang

Loeve

Lubineau

Markovinovic

Moës

Niroomandi

P. Gosselet

P. Kerfriden

Pebrel

Risler

Ryckelynck

S. Adhikari

S.P.A. Bordas

Schellenkens

Sirovich

Yvonnet

English

arXiv

This article describes a bridge between POD-based model order reduction techniques and the classical Newton/Krylov solvers. This bridge is used to derive an efficient algorithm to correct, “on-the-fly”, the reduced order modelling of highly nonlinear problems undergoing strong topological changes. Damage initiation problems tackled via a corrected hyperreduction method are used as an example. It is shown that the relevancy of reduced order model can be significantly improved with reasonable additional costs when using this algorithm, even when strong topological changes are involved

Kerfriden, Pierre

Gosselet, P.

Adhikari, S.

Bordas, Stephane Pierre Alain

Online Research @ Cardiff

Bridging proper orthogonal decomposition methods and augmented Newton-Krylov algorithms: An adaptive model order reduction for highly nonlinear mechanical problems

peer reviewedThis article describes a bridge between POD-based model order reduction techniques and the classical Newton/Krylov solvers. This bridge is used to derive an efficient algorithm to correct, " on-the-fly" , the reduced order modelling of highly nonlinear problems undergoing strong topological changes. Damage initiation problems tackled via a corrected hyperreduction method are used as an example. It is shown that the relevancy of reduced order model can be significantly improved with reasonable additional costs when using this algorithm, even when strong topological changes are involved. © 2010.Towards the next generation surgical simulator

Kerfriden, P.

Bordas, Stéphane

Open Repository and Bibliography - Luxembourg

This article describes a bridge between POD-based model order reduction techniques and the classical Newton/Krylov solvers. This bridge is used to derive an efficient algo-rithm to correct, “on-the-fly”, the reduced order modelling of highly nonlinear problems undergoing strong topological changes. Damage initiation problems are addressed and tackle via a corrected hyperreduction method. It is shown that the relevancy of reduced order model can be significantly improved with reasonable additional costs when using this algorithm, even when strong topological changes are involved

S. Bordas

CiteSeerX

Crossref

Bridging proper orthogonal decomposition methods and augmented Newton–Krylov algorithms: An adaptive model order reduction for highly nonlinear mechanical problems

Adhikari, Sondipon

Bordas, S.P.A.

Enlighten

http://orbilu.uni.lu/bitstream/10993/14475/1/POD_Krylov_CMAME.pdf

Bridging Proper Orthogonal Decomposition methods and augmented
  Newton-Krylov algorithms: an adaptive model order reduction for highly
  nonlinear mechanical problems

Bridging Proper Orthogonal Decomposition methods and augmented Newton-Krylov algorithms: an adaptive model order reduction for highly nonlinear mechanical problems

Abstract

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Online Research @ Cardiff

Open Repository and Bibliography - Luxembourg

CiteSeerX

Crossref

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