Microstructure-informed deep learning model for accurate prediction of multiple concrete properties
Microstructure-informed deep learning model for accurate prediction of multiple concrete properties
Predicting multiple properties of concrete using empirical models has become increasingly challenging due to the complexity of modern concrete formulations and the nonlinear behavior of their constituents. This study introduces a sequential model that integrates mix proportions with microstructural information of concrete. The model addresses the limitations of small datasets and the inherent variability in concrete's raw materials and production processes. A novel dataset comprising concrete mix proportions, 56,160 scanning electron microscope images, and their corresponding macroscopic properties was constructed for training and validation. We developed a sequential model integrating a Swin Transformer (Swin-T) with a Back Propagation Neural Network (BPNN), achieving superior accuracy in predicting compressive strength and permeability. Comprehensive evaluations using SHAP and GradCAM reveal the critical role of hydration products in these predictions, underscoring the enhanced interpretability and efficacy of our approach. This work advocates for the integration of microstructural insights to improve the reliability and precision of concrete assessments.
Li, Ye
86d13351-982d-46c3-9347-22794f647f86
Ma, Yiming
ec7c6106-8faa-40be-b3d1-5b1a1c330cd7
Tan, Kang Hai
d6b202e6-50ba-4236-961a-c9be0cb46e5c
Qian, Hanjie
7ebd2a2e-335f-4b30-8b38-76add7a93791
Liu, Tiejun
07e72a65-be75-4b13-b54d-9ed949c93470
16 November 2024
Li, Ye
86d13351-982d-46c3-9347-22794f647f86
Ma, Yiming
ec7c6106-8faa-40be-b3d1-5b1a1c330cd7
Tan, Kang Hai
d6b202e6-50ba-4236-961a-c9be0cb46e5c
Qian, Hanjie
7ebd2a2e-335f-4b30-8b38-76add7a93791
Liu, Tiejun
07e72a65-be75-4b13-b54d-9ed949c93470
Li, Ye, Ma, Yiming, Tan, Kang Hai, Qian, Hanjie and Liu, Tiejun
(2024)
Microstructure-informed deep learning model for accurate prediction of multiple concrete properties.
Journal of Building Engineering, 98, [111339].
(doi:10.1016/j.jobe.2024.111339).
Abstract
Predicting multiple properties of concrete using empirical models has become increasingly challenging due to the complexity of modern concrete formulations and the nonlinear behavior of their constituents. This study introduces a sequential model that integrates mix proportions with microstructural information of concrete. The model addresses the limitations of small datasets and the inherent variability in concrete's raw materials and production processes. A novel dataset comprising concrete mix proportions, 56,160 scanning electron microscope images, and their corresponding macroscopic properties was constructed for training and validation. We developed a sequential model integrating a Swin Transformer (Swin-T) with a Back Propagation Neural Network (BPNN), achieving superior accuracy in predicting compressive strength and permeability. Comprehensive evaluations using SHAP and GradCAM reveal the critical role of hydration products in these predictions, underscoring the enhanced interpretability and efficacy of our approach. This work advocates for the integration of microstructural insights to improve the reliability and precision of concrete assessments.
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JBE-D-24-12232_R1
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Restricted to Repository staff only until 16 November 2026.
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Accepted/In Press date: 12 November 2024
e-pub ahead of print date: 13 November 2024
Published date: 16 November 2024
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Local EPrints ID: 498342
URI: http://eprints.soton.ac.uk/id/eprint/498342
PURE UUID: 5de7bbbe-1bff-47d7-988e-acb15b97aaae
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Date deposited: 17 Feb 2025 17:36
Last modified: 18 Feb 2025 03:12
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Contributors
Author:
Ye Li
Author:
Yiming Ma
Author:
Kang Hai Tan
Author:
Hanjie Qian
Author:
Tiejun Liu
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