Full-field prediction of stress and fracture patterns in composites using deep learning and self-attention

Yang Chen; Tim Dodwell; Tomas Chuaqui; Richard Butler

doi:10.1016/j.engfracmech.2023.109314

Full-field prediction of stress and fracture patterns in composites using deep learning and self-attention

Yang Chen, Tim Dodwell, Tomas Chuaqui, Richard Butler

Research output: Contribution to journal › Article › peer-review

21 Citations (SciVal)

Abstract

An efficient surrogate modelling framework is proposed for full-field predictions of stresses and cracks in composite material microstructures. The framework comprises two sequential convolutional neural networks (CNNs), predicting the elastic stress fields and the local crack maps, respectively. Training and test data are created from high-resolution fracture simulations of randomly generated representative volume elements (RVEs), including geometric variabilities such as fibre volume fraction and porosity. This work shows that the inclusion of a self-attention layer within the network enables the model to capture relevant local and global features, which are important in determining the heterogeneous stress distribution and crack patterns. The performance of the trained CNN models is evaluated with unseen data. The CNN models speed up the full-field predictions by 3 ∼ 4 orders of magnitude compared to the physics-based model. The surrogate model's accuracy and efficiency are key enables for applications such as multiscale simulation, microstructure optimisation and uncertainty quantification.

Original language	English
Article number	109314
Journal	Engineering Fracture Mechanics
Volume	286
Early online date	4 May 2023
DOIs	https://doi.org/10.1016/j.engfracmech.2023.109314
Publication status	Published - 27 Jun 2023

Bibliographical note

Funding Information:
The authors gratefully acknowledge the financial support from the Engineering and Physical Sciences Research Council, who funded the project “Certification for Design – Reshaping the Testing Pyramid” (CerTest, EP/S017038/1) and the Future Composites Manufacturing Research Hub (EP/P006701/1), for which YC holds the Innovation Fellowship. The financial support from the West of England Combined Authority through the project “Digital Engineering Technology & Innovation” (DETI) is also acknowledged.

Data availability
Data will be made available on request.

Funding

The authors gratefully acknowledge the financial support from the Engineering and Physical Sciences Research Council, who funded the project “Certification for Design – Reshaping the Testing Pyramid” (CerTest, EP/S017038/1) and the Future Composites Manufacturing Research Hub (EP/P006701/1), for which YC holds the Innovation Fellowship. The financial support from the West of England Combined Authority through the project “Digital Engineering Technology & Innovation” (DETI) is also acknowledged.

Keywords

Composites
Convolutional Neural Network
Fracture
Full-field prediction
Self-Attention

ASJC Scopus subject areas

General Materials Science
Mechanics of Materials
Mechanical Engineering

Access to Document

10.1016/j.engfracmech.2023.109314Licence: CC BY

Cite this

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title = "Full-field prediction of stress and fracture patterns in composites using deep learning and self-attention",

abstract = "An efficient surrogate modelling framework is proposed for full-field predictions of stresses and cracks in composite material microstructures. The framework comprises two sequential convolutional neural networks (CNNs), predicting the elastic stress fields and the local crack maps, respectively. Training and test data are created from high-resolution fracture simulations of randomly generated representative volume elements (RVEs), including geometric variabilities such as fibre volume fraction and porosity. This work shows that the inclusion of a self-attention layer within the network enables the model to capture relevant local and global features, which are important in determining the heterogeneous stress distribution and crack patterns. The performance of the trained CNN models is evaluated with unseen data. The CNN models speed up the full-field predictions by 3 ∼ 4 orders of magnitude compared to the physics-based model. The surrogate model's accuracy and efficiency are key enables for applications such as multiscale simulation, microstructure optimisation and uncertainty quantification.",

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author = "Yang Chen and Tim Dodwell and Tomas Chuaqui and Richard Butler",

note = "Funding Information: The authors gratefully acknowledge the financial support from the Engineering and Physical Sciences Research Council, who funded the project “Certification for Design – Reshaping the Testing Pyramid” (CerTest, EP/S017038/1) and the Future Composites Manufacturing Research Hub (EP/P006701/1), for which YC holds the Innovation Fellowship. The financial support from the West of England Combined Authority through the project “Digital Engineering Technology & Innovation” (DETI) is also acknowledged. Data availability Data will be made available on request.",

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doi = "10.1016/j.engfracmech.2023.109314",

language = "English",

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Y1 - 2023/6/27

N2 - An efficient surrogate modelling framework is proposed for full-field predictions of stresses and cracks in composite material microstructures. The framework comprises two sequential convolutional neural networks (CNNs), predicting the elastic stress fields and the local crack maps, respectively. Training and test data are created from high-resolution fracture simulations of randomly generated representative volume elements (RVEs), including geometric variabilities such as fibre volume fraction and porosity. This work shows that the inclusion of a self-attention layer within the network enables the model to capture relevant local and global features, which are important in determining the heterogeneous stress distribution and crack patterns. The performance of the trained CNN models is evaluated with unseen data. The CNN models speed up the full-field predictions by 3 ∼ 4 orders of magnitude compared to the physics-based model. The surrogate model's accuracy and efficiency are key enables for applications such as multiscale simulation, microstructure optimisation and uncertainty quantification.

AB - An efficient surrogate modelling framework is proposed for full-field predictions of stresses and cracks in composite material microstructures. The framework comprises two sequential convolutional neural networks (CNNs), predicting the elastic stress fields and the local crack maps, respectively. Training and test data are created from high-resolution fracture simulations of randomly generated representative volume elements (RVEs), including geometric variabilities such as fibre volume fraction and porosity. This work shows that the inclusion of a self-attention layer within the network enables the model to capture relevant local and global features, which are important in determining the heterogeneous stress distribution and crack patterns. The performance of the trained CNN models is evaluated with unseen data. The CNN models speed up the full-field predictions by 3 ∼ 4 orders of magnitude compared to the physics-based model. The surrogate model's accuracy and efficiency are key enables for applications such as multiscale simulation, microstructure optimisation and uncertainty quantification.

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Full-field prediction of stress and fracture patterns in composites using deep learning and self-attention

Abstract

Bibliographical note

Funding

Keywords

ASJC Scopus subject areas

Access to Document

Other files and links

Fingerprint

Future Composites Manufacturing Research Hub: Permeability assessment for Liquid Composites Moulding

DETI - PoC2 - Modelling framework

Cite this

Full-field prediction of stress and fracture patterns in composites using deep learning and self-attention

Abstract

Bibliographical note

Funding

Keywords

ASJC Scopus subject areas

Access to Document

Other files and links

Fingerprint

Projects

Future Composites Manufacturing Research Hub: Permeability assessment for Liquid Composites Moulding

DETI - PoC2 - Modelling framework

Cite this