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Engineering with Computers

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31-03-2024 | Original Article

Performance evaluation of deep learning approaches for predicting mechanical fields in composites

Authors: Marwa Yacouti, Maryam Shakiba

Published in: Engineering with Computers | Issue 5/2024

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Abstract

This paper presents a rigorous and critical methodology for evaluating the performance of deep learning (DL) techniques in predicting mechanical responses within the microstructural representation of composites. In the past few years, deep learning has emerged as a powerful tool and an efficient surrogate for finite element analysis in computational mechanics. This research addresses questions regarding the suitability of common error metrics for evaluating the accuracy of DL techniques in predicting full-field mechanical responses of composites. Through comparative analysis, we evaluate the performance and identify the limitations of two DL frameworks in predicting the linear von Mises stress distribution within the microstructure of the selected fiber-reinforced composite. The first DL method is based on the residual network, while the second utilizes U-Net architecture. We use several evaluation metrics, including different types of error and statistical measures and examine their suitability. Additionally, this study also investigates the influence of the size of the training and validation dataset, ranging from 50 to 2000 samples, on the predictive performance of the employed ResNet and U-Net based approaches.

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Title: Performance evaluation of deep learning approaches for predicting mechanical fields in composites
Authors: Marwa Yacouti
Maryam Shakiba
Publication date: 31-03-2024
Publisher: Springer London
Published in: Engineering with Computers / Issue 5/2024
Print ISSN: 0177-0667
Electronic ISSN: 1435-5663
DOI: https://doi.org/10.1007/s00366-024-01966-4

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Abstract

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Springer Professional "Technik"

Springer Professional "Wirtschaft+Technik"

Springer Professional "Wirtschaft"

Reinforcement learning for block decomposition of planar CAD models

Towards a comprehensive damage identification of structures through populations of competing models

Image-based biomarkers for engineering neuroblastoma patient-specific computational models

A novel normalized reduced-order physics-informed neural network for solving inverse problems

A smooth single-variable-based interpolation function for multi-material topology optimization

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