TRANSDISCIPLINARY INSIGHT |
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Multiscale computation on feedforward neural network and recurrent neural network |
Bin LI, Xiaoying ZHUANG() |
Department of Geotechnical Engineering, Tongji University, Shanghai 200092, China |
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Abstract Homogenization methods can be used to predict the effective macroscopic properties of materials that are heterogenous at micro- or fine-scale. Among existing methods for homogenization, computational homogenization is widely used in multiscale analyses of structures and materials. Conventional computational homogenization suffers from long computing times, which substantially limits its application in analyzing engineering problems. The neural networks can be used to construct fully decoupled approaches in nonlinear multiscale methods by mapping macroscopic loading and microscopic response. Computational homogenization methods for nonlinear material and implementation of offline multiscale computation are studied to generate data set. This article intends to model the multiscale constitution using feedforward neural network (FNN) and recurrent neural network (RNN), and appropriate set of loading paths are selected to effectively predict the materials behavior along unknown paths. Applications to two-dimensional multiscale analysis are tested and discussed in detail.
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Keywords
multiscale method
constitutive model
feedforward neural network
recurrent neural network
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Corresponding Author(s):
Xiaoying ZHUANG
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Just Accepted Date: 20 November 2020
Online First Date: 28 December 2020
Issue Date: 12 January 2021
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