Title of article
Multiscale computational homogenization methods with a gradient enhanced scheme based on the discontinuous Galerkin formulation
Author/Authors
Nguyen، نويسنده , , V.-D. and Becker، نويسنده , , G. and Noels، نويسنده , , L.، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2013
Pages
15
From page
63
To page
77
Abstract
When considering problems of dimensions close to the characteristic length of the material, the size effects can not be neglected and the classical (so-called first-order) multiscale computational homogenization scheme (FMCH) looses accuracy, motivating the use of a second-order multiscale computational homogenization (SMCH) scheme. This second-order scheme uses the classical continuum at the micro-scale while considering a second-order continuum at the macro-scale. Although the theoretical background of the second-order continuum is increasing, the implementation into a finite element code is not straightforward because of the lack of high-order continuity of the shape functions. In this work, we propose a SMCH scheme relying on the discontinuous Galerkin (DG) method at the macro-scale, which simplifies the implementation of the method. Indeed, the DG method is a generalization of weak formulations allowing for inter-element discontinuities either at the C 0 level or at the C 1 level, and it can thus be used to constrain weakly the C 1 continuity at the macro-scale. The C 0 continuity can be either weakly constrained by using the DG method or strongly constrained by using usual C 0 displacement-based finite elements. Therefore, two formulations can be used at the macro-scale: (i) the full-discontinuous Galerkin formulation (FDG) with weak C 0 and C 1 continuity enforcements, and (ii) the enriched discontinuous Galerkin formulation (EDG) with high-order term enrichment into the conventional C 0 finite element framework. The micro-problem is formulated in terms of standard equilibrium and periodic boundary conditions. A parallel implementation in three dimensions for non-linear finite deformation problems is developed, showing that the proposed method can be integrated into conventional finite element codes in a straightforward and efficient way.
Keywords
second-order , discontinuous Galerkin , FEM , Periodic condition , Computational homogenization , Heterogeneous Materials
Journal title
Computer Methods in Applied Mechanics and Engineering
Serial Year
2013
Journal title
Computer Methods in Applied Mechanics and Engineering
Record number
1595979
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