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Examination of load-deformation characteristics of long-span bridges in harsh natural environments based on real-time updating artificial neural network

journal contribution
posted on 2024-04-15, 15:26 authored by Liangliang Hu, Xiaolin Meng, Yilin Xie, Craig HancockCraig Hancock, George Ye, Yan Bao

Long-span bridges, often exposed to challenging harsh natural environments with severe weather conditions, necessitate real-time examination of load-deformation characteristics to ensure structural integrity and safety. Previous studies have primarily focused on investigating the causes of deformation in bridge structures under different single-load conditions during severe natural disasters, utilizing physics-based, mechanics-based, and data-driven methods. However, these methods cannot achieve fully achieve effective analysis of the real-time effects of multi-factor loads on bridge deformation, particularly in the presence of dynamic and simultaneous loads such as wind or temperature variations. A novel data-driven method is proposed based on a state-of-the-art real-time updating artificial neural networks (ANNs) algorithm to investigate the real-time coupling relationship between multi-loads and bridge deformation, enabling real-time prediction of bridge deformations. Additionally, the real-time characteristics between structural deformation and multi-loads are explained by incorporating SHapley Additive exPlanation (SHAP) in harsh natural environments. The proposed method has been validated on the 1,006-meter Forth Bridge in Scotland, showing high accuracy in real-time displacement prediction. The 9-day testing dataset demonstrated the R2 values for Y and Z direction deformations were found to be 0.98 and 0.87, respectively. The performance metrics for each day indicated that the majority of Y and Z direction deformations had R2 values exceeding 0.8, with RMSE and MAE values below 30 mm. The SHAP analysis revealed that an increase in wind speed leads to intensified Y direction deformation (larger SHAP values), while temperature has a significant impact on Z direction deformation (smaller SHAP values). Moreover, the weight influences of each load on the deformation are not fixed. The study's findings demonstrate that the proposed method enables accurate long-term prediction and assessment, allowing precise monitoring and prevention of abnormal risks in bridges under harsh environmental conditions.

Funding

European Space Agency (ESA) contract numbers 4000116646/16/NL/US and 4000108996/13/NL/US

Research on Deformation Observation of Landslides and Large Engineering Structures Based on High-Precision GNSS and Micro-UAV LiDAR Technology

National Natural Science Foundation of China

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National Natural Science Foundation of China (grant No. 52378385)

National Key Research and Development Program of China (2023YFE0208200)

History

School

  • Architecture, Building and Civil Engineering

Published in

Engineering Structures

Volume

308

Publisher

Elsevier BV

Version

  • AM (Accepted Manuscript)

Rights holder

© Elsevier Ltd

Publisher statement

This paper was accepted for publication in the journal Engineering Structures and the definitive published version is available at https://doi.org/10.1016/j.engstruct.2024.118022

Acceptance date

2024-04-08

Publication date

2024-04-12

Copyright date

2024

ISSN

0141-0296

eISSN

1873-7323

Language

  • en

Depositor

Dr Craig Hancock. Deposit date: 15 April 2024

Article number

118022