2019
DOI: 10.1016/j.cma.2019.01.016
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An inverse micro-mechanical analysis toward the stochastic homogenization of nonlinear random composites

Abstract: An inverse Mean-Field Homogenization (MFH) process is developed to improve the computational efficiency of non-linear stochastic multiscale analyzes by relying on a micro-mechanics model. First full-field simulations of composite Stochastic Volume Element (SVE) realizations are performed to characterize the homogenized stochastic behavior. The uncertainties observed in the non-linear homogenized response, which result from the uncertainties of their micro-structures, are then translated to an incrementalsecant… Show more

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Cited by 20 publications
(33 citation statements)
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“…In future works, this MFH model will be used to construct a mean‐field stochastic reduced order model (MF‐ROM), 81 which will allow to perform macroscale simulations of composites with pressure‐dependent matrix materials accounting for the inherent stochastic properties caused by geometrical perturbations in the microstructure.…”
Section: Discussionmentioning
confidence: 99%
See 1 more Smart Citation
“…In future works, this MFH model will be used to construct a mean‐field stochastic reduced order model (MF‐ROM), 81 which will allow to perform macroscale simulations of composites with pressure‐dependent matrix materials accounting for the inherent stochastic properties caused by geometrical perturbations in the microstructure.…”
Section: Discussionmentioning
confidence: 99%
“…$$ This expression corresponds to a first order approximation of the normal direction in the stress space in terms of normalΔbold-italicε$$ \Delta \boldsymbol{\varepsilon} $$. As discussed by Wu et al, 81 for infinitesimal strain increments normalΔbold-italicε0$$ \Delta \boldsymbol{\varepsilon} \to 0 $$ for a single phase material, this expression boldNn+1$$ {\mathbf{N}}_{n+1} $$ tends to the normal of the yield surface. At the trial state, boldNn+1tr$$ {\mathbf{N}}_{n+1}^{\mathrm{tr}} $$ writes: boldNn+1tr=3()bold-italicCel:normalΔbold-italicεn+1normalrdev+2β3()bold-italicCel:normalΔbold-italicεn+1normalrvol=3()truebold-italicσ^n+1trprefix−truebold-italicσ^nresdev+2β3()truebold-italicσ^n+1trprefix−truebold-italicσ^nresvol.$$ {\mathbf{N}}_{n+1}^{\mathrm{tr}}=3{\left({\boldsymbol{C}}^{\mathrm{el}}:\Delta {\boldsymbol{\varepsilon}}_{n+1}^{\mathrm{r}}\right)}^{\mathrm{dev}}+\frac{2\beta }{3}{\left({\boldsymbol{C}}^{\mathrm{el}}:\Delta {\boldsymbol{\varepsilon}}_{n+1}^{\mathrm{r}}\right)}^{\mathrm{vol}}=3{\left({\hat{\boldsymbol{\sigma}}}_{n+1}^{\mathrm{tr}}-{\hat{\boldsymbol{\sigma}}}_n^{\mathrm{r}\mathrm{es}}\right)}^{\mathrm{dev}}+\frac{2\beta }{3}{\left({\hat{\boldsymbol{\sigma}}}_{n...…”
Section: Pressure Sensitive Phase Materials Lawmentioning
confidence: 99%
“…However, if crack paths are unknown in advance, this strategy becomes less efficient. Indeed, to handle crack propagation along arbitrary trajectories, one must use special adaptive procedures, involving remeshing, 19,20 nodal relocation, 21–25 and multiscale strategies 26–30 …”
Section: Introductionmentioning
confidence: 99%
“…Firstly, we need to design a suitable model of the microstructure and transfer macroscopic loads and deformations to the microscale. This is done using the Hill-Mandel [14,23,44,45,54] condition which states that the virtual work performed by microscopic stresses at microscopic deformation gradients must be equal to the virtual work performed by macroscopic (homogenized) stresses at macroscopic (homogenized) deformation gradients. The second step is to simulate the response of the micromodel.…”
Section: Introductionmentioning
confidence: 99%
“…This reduction results however in a highly sophisticated stochastic problem with discontinuous random fields. It is worth to notice that a similar approach towards the homogenization of elasto-plastic materials with random microstructure was recently developed in [54].…”
Section: Introductionmentioning
confidence: 99%