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Deep active learning for constitutive modelling of granular materials: From representative volume elements to implicit finite element modelling
Tongming QU,
Shaoheng Guan Guan,
Yuntian Feng 
,
Gang Ma,
Wei Zhou,
Jidong Zhao
,
Gang Ma,
Wei Zhou,
Jidong Zhao
International Journal of Plasticity, Volume: 164, Start page: 103576
Swansea University Authors:
Tongming QU, Shaoheng Guan Guan, Yuntian Feng
-
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DOI (Published version): 10.1016/j.ijplas.2023.103576
Abstract
Constitutive relation remains one of the most important, yet fundamental challenges in the study of granular materials. Instead of using closed-form phenomenological models or numerical multiscale modelling, machine learning has emerged as an alternative paradigm to revolutionise the constitutive mo...
| Published in: | International Journal of Plasticity |
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| ISSN: | 0749-6419 1879-2154 |
| Published: |
Elsevier BV
2023
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| URI: | https://cronfa.swan.ac.uk/Record/cronfa62759 |
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Instead of using closed-form phenomenological models or numerical multiscale modelling, machine learning has emerged as an alternative paradigm to revolutionise the constitutive modelling of granular materials. However, deep neural networks (DNNs) require massive training data and often fail to make credible extrapolations. This study aims to develop a deep active learning strategy to (i) identify unreliable forecasts without knowing the ground truth; and (ii) continuously improve and verify a data-driven constitutive model until the desired generalisation is satisfied. The role of active learning in constitutive modelling is instantiated through three scenarios: (i) off-line strain-stress data pool of granular materials; (ii) interactive constitutive training and strain-stress data labelling; and (iii) finite element modelling (FEM) driven by deep learning-based constitutive models. The results confirm the capability of active learning in advancing data-driven constitutive modelling of granular materials toward developing a faithful surrogate constitutive model with less data. 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v2 62759 2023-02-27 Deep active learning for constitutive modelling of granular materials: From representative volume elements to implicit finite element modelling 1a8144ef1058bc1310206808a4d274c3 Tongming QU Tongming QU true false 8be5dace79e94a4d0abd32215a13f806 Shaoheng Guan Guan Shaoheng Guan Guan true false d66794f9c1357969a5badf654f960275 0000-0002-6396-8698 Yuntian Feng Yuntian Feng true false 2023-02-27 FGSEN Constitutive relation remains one of the most important, yet fundamental challenges in the study of granular materials. Instead of using closed-form phenomenological models or numerical multiscale modelling, machine learning has emerged as an alternative paradigm to revolutionise the constitutive modelling of granular materials. However, deep neural networks (DNNs) require massive training data and often fail to make credible extrapolations. This study aims to develop a deep active learning strategy to (i) identify unreliable forecasts without knowing the ground truth; and (ii) continuously improve and verify a data-driven constitutive model until the desired generalisation is satisfied. The role of active learning in constitutive modelling is instantiated through three scenarios: (i) off-line strain-stress data pool of granular materials; (ii) interactive constitutive training and strain-stress data labelling; and (iii) finite element modelling (FEM) driven by deep learning-based constitutive models. The results confirm the capability of active learning in advancing data-driven constitutive modelling of granular materials toward developing a faithful surrogate constitutive model with less data. The same active learning strategy can also be applied to other data-centric applications across various science and engineering fields. Journal Article International Journal of Plasticity 164 103576 Elsevier BV 0749-6419 1879-2154 Granular materials; Machine learning; Constitutive models; Active learning; Discrete element model; Finite element model 1 5 2023 2023-05-01 10.1016/j.ijplas.2023.103576 http://dx.doi.org/10.1016/j.ijplas.2023.103576 COLLEGE NANME Science and Engineering - Faculty COLLEGE CODE FGSEN Swansea University The study was financially supported by National Natural Science Foundation of China (via General Project #11972030) and Research Grants Council of Hong Kong (under GRF #16208720). 2023-06-01T16:24:39.0496424 2023-02-27T13:22:03.5318505 Faculty of Science and Engineering School of Aerospace, Civil, Electrical, General and Mechanical Engineering - Civil Engineering Tongming QU 1 Shaoheng Guan Guan 2 Yuntian Feng 0000-0002-6396-8698 3 Gang Ma 4 Wei Zhou 5 Jidong Zhao 6 62759__26899__8c8071f8dd4c495ea444920678566677.pdf 62759.pdf 2023-03-20T10:21:53.4581055 Output 12578670 application/pdf Version of Record true © 2023 The Author(s). Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/). true eng http://creativecommons.org/licenses/by-nc-nd/4.0/ |
| title |
Deep active learning for constitutive modelling of granular materials: From representative volume elements to implicit finite element modelling |
| spellingShingle |
Deep active learning for constitutive modelling of granular materials: From representative volume elements to implicit finite element modelling Tongming QU Shaoheng Guan Guan Yuntian Feng |
| title_short |
Deep active learning for constitutive modelling of granular materials: From representative volume elements to implicit finite element modelling |
| title_full |
Deep active learning for constitutive modelling of granular materials: From representative volume elements to implicit finite element modelling |
| title_fullStr |
Deep active learning for constitutive modelling of granular materials: From representative volume elements to implicit finite element modelling |
| title_full_unstemmed |
Deep active learning for constitutive modelling of granular materials: From representative volume elements to implicit finite element modelling |
| title_sort |
Deep active learning for constitutive modelling of granular materials: From representative volume elements to implicit finite element modelling |
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1a8144ef1058bc1310206808a4d274c3 8be5dace79e94a4d0abd32215a13f806 d66794f9c1357969a5badf654f960275 |
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1a8144ef1058bc1310206808a4d274c3_***_Tongming QU 8be5dace79e94a4d0abd32215a13f806_***_Shaoheng Guan Guan d66794f9c1357969a5badf654f960275_***_Yuntian Feng |
| author |
Tongming QU Shaoheng Guan Guan Yuntian Feng |
| author2 |
Tongming QU Shaoheng Guan Guan Yuntian Feng Gang Ma Wei Zhou Jidong Zhao |
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International Journal of Plasticity |
| container_volume |
164 |
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103576 |
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2023 |
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Swansea University |
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0749-6419 1879-2154 |
| doi_str_mv |
10.1016/j.ijplas.2023.103576 |
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Elsevier BV |
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Faculty of Science and Engineering |
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http://dx.doi.org/10.1016/j.ijplas.2023.103576 |
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| description |
Constitutive relation remains one of the most important, yet fundamental challenges in the study of granular materials. Instead of using closed-form phenomenological models or numerical multiscale modelling, machine learning has emerged as an alternative paradigm to revolutionise the constitutive modelling of granular materials. However, deep neural networks (DNNs) require massive training data and often fail to make credible extrapolations. This study aims to develop a deep active learning strategy to (i) identify unreliable forecasts without knowing the ground truth; and (ii) continuously improve and verify a data-driven constitutive model until the desired generalisation is satisfied. The role of active learning in constitutive modelling is instantiated through three scenarios: (i) off-line strain-stress data pool of granular materials; (ii) interactive constitutive training and strain-stress data labelling; and (iii) finite element modelling (FEM) driven by deep learning-based constitutive models. The results confirm the capability of active learning in advancing data-driven constitutive modelling of granular materials toward developing a faithful surrogate constitutive model with less data. The same active learning strategy can also be applied to other data-centric applications across various science and engineering fields. |
| published_date |
2023-05-01T16:24:37Z |
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11.013148 |