Model Order Reduction in Computational Multiscale Fracture Mechanics

M. Caicedo; J. Oliver; A.E. Huespe; O. Lloberas-Valls

doi:10.4028/www.scientific.net/KEM.713.248

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 713Model Order Reduction in Computational Multiscale...

Model Order Reduction in Computational Multiscale Fracture Mechanics

Abstract:

Nowadays, the model order reduction techniques have become an intensive research eld because of the increasing interest in the computational modeling of complex phenomena in multi-physic problems, and its conse- quent increment in high-computing demanding processes; it is well known that the availability of high-performance computing capacity is, in most of cases limited, therefore, the model order reduction becomes a novelty tool to overcome this paradigm, that represents an immediately challenge in our research community. In computational multiscale modeling for instance, in order to study the interaction between components, a di erent numerical model has to be solved in each scale, this feature increases radically the computational cost. We present a reduced model based on a multi-scale framework for numerical modeling of the structural failure of heterogeneous quasi-brittle materials using the Strong Discontinuity Approach (CSD). The model is assessed by application to cementitious materials. The Proper Orthogonal Decomposition (POD) and the Reduced Order Integration Cubature are the pro- posed techniques to develop the reduced model, these two techniques work together to reduce both, the complexity and computational time of the high-delity model, in our case the FE² standard model

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Periodical:

Key Engineering Materials (Volume 713)

Pages:

248-253

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.713.248

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Online since:

September 2016

Authors:

M. Caicedo*, J. Oliver, A.E. Huespe, O. Lloberas-Valls

Keywords:

Computational Multi-Scale Modeling, Continuum Strong Discontinuituy Approach, Fracture, Model Order Reduction, Reduced-Order Cubature

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* - Corresponding Author

References

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