Wheel-rail force identification for high-speed railway based on a modified weighted l₁-norm regularization with optimal strain sensors
Wheel-rail force identification is an important inverse problem for structural health monitoring of high-speed railway train-track-bridge system. It is widely used for dynamic response reconstruction of bridges and early safety warning of dynamic reduction rate of wheel weight for the train. It can...
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sg-ntu-dr.10356-1700562023-08-22T08:46:28Z Wheel-rail force identification for high-speed railway based on a modified weighted l₁-norm regularization with optimal strain sensors Wang, Xin Yang, Yaowen Li, Shunlong Zhuo, Yi Meng, Fanzeng School of Civil and Environmental Engineering Engineering::Civil engineering Dynamic Loads Genetic Algorithm Wheel-rail force identification is an important inverse problem for structural health monitoring of high-speed railway train-track-bridge system. It is widely used for dynamic response reconstruction of bridges and early safety warning of dynamic reduction rate of wheel weight for the train. It can also serve as a reference for the calibration of wheel-rail force model. This paper proposes a wheel-rail force identification method for high-speed railway based on a modified weighted l1-norm regularization. Based on numerical simulations, it is found that variations of dynamic component of wheel-rail forces are very small. Therefore, the problem is transformed into the identification of three categories of static wheel weights and two categories of average dynamic components, which greatly simplifies the degree of freedom of the solution compared to traditional methods, thereby improving the solution accuracy and saving the number of sensors needed. The wheel-rail forces are decomposed into the product of a series of redundant basis functions and corresponding coefficients. The fast iterative shrinkage threshold algorithm (FISTA) and the Bayesian information criterion (BIC) are used to seek the solution of l1-norm regularization and to select the optimal regularization coefficients, respectively. Since the number of sensors and their locations have a significant impact on the accuracy of reconstructed wheel-rail forces, they are optimized using a genetic algorithm (GA), aiming to accurately reconstruct the wheel-rail forces with the minimum number of sensors at corresponding optimal positions. Numerical simulation of a 32 m box girder standard beam for high-speed railway shows that the reconstructed wheel-rail forces are in good agreement with the simulated results, which verifies the accuracy of the proposed method. In addition, the results of dynamic load test indirectly demonstrate the effectiveness of the proposed method. National Research Foundation (NRF) Financial support for this study was provided by NSFC for Excellent Young Scholars [51922034], Heilongjiang Natural Science Foundation for Excellent Young Scholars [YQ2019E025], China Railway Design Corporation R&D Program [2020YY240604], and Fundamental Research Funds for the Central Universities [FRFCU5710051018]. This research is also supported by the National Research Foundation, Singapore under its AI Singapore Programme (AISG Award No: AISG2-TC-2021-001). 2023-08-22T08:46:27Z 2023-08-22T08:46:27Z 2023 Journal Article Wang, X., Yang, Y., Li, S., Zhuo, Y. & Meng, F. (2023). Wheel-rail force identification for high-speed railway based on a modified weighted l₁-norm regularization with optimal strain sensors. Mechanical Systems and Signal Processing, 198, 110429-. https://dx.doi.org/10.1016/j.ymssp.2023.110429 0888-3270 https://hdl.handle.net/10356/170056 10.1016/j.ymssp.2023.110429 2-s2.0-85157985867 198 110429 en AISG2-TC-2021-001 Mechanical Systems and Signal Processing © 2023 Elsevier Ltd. All rights reserved. |
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Engineering::Civil engineering Dynamic Loads Genetic Algorithm Wang, Xin Yang, Yaowen Li, Shunlong Zhuo, Yi Meng, Fanzeng Wheel-rail force identification for high-speed railway based on a modified weighted l₁-norm regularization with optimal strain sensors |
| description |
Wheel-rail force identification is an important inverse problem for structural health monitoring of high-speed railway train-track-bridge system. It is widely used for dynamic response reconstruction of bridges and early safety warning of dynamic reduction rate of wheel weight for the train. It can also serve as a reference for the calibration of wheel-rail force model. This paper proposes a wheel-rail force identification method for high-speed railway based on a modified weighted l1-norm regularization. Based on numerical simulations, it is found that variations of dynamic component of wheel-rail forces are very small. Therefore, the problem is transformed into the identification of three categories of static wheel weights and two categories of average dynamic components, which greatly simplifies the degree of freedom of the solution compared to traditional methods, thereby improving the solution accuracy and saving the number of sensors needed. The wheel-rail forces are decomposed into the product of a series of redundant basis functions and corresponding coefficients. The fast iterative shrinkage threshold algorithm (FISTA) and the Bayesian information criterion (BIC) are used to seek the solution of l1-norm regularization and to select the optimal regularization coefficients, respectively. Since the number of sensors and their locations have a significant impact on the accuracy of reconstructed wheel-rail forces, they are optimized using a genetic algorithm (GA), aiming to accurately reconstruct the wheel-rail forces with the minimum number of sensors at corresponding optimal positions. Numerical simulation of a 32 m box girder standard beam for high-speed railway shows that the reconstructed wheel-rail forces are in good agreement with the simulated results, which verifies the accuracy of the proposed method. In addition, the results of dynamic load test indirectly demonstrate the effectiveness of the proposed method. |
| author2 |
School of Civil and Environmental Engineering |
| author_facet |
School of Civil and Environmental Engineering Wang, Xin Yang, Yaowen Li, Shunlong Zhuo, Yi Meng, Fanzeng |
| format |
Article |
| author |
Wang, Xin Yang, Yaowen Li, Shunlong Zhuo, Yi Meng, Fanzeng |
| author_sort |
Wang, Xin |
| title |
Wheel-rail force identification for high-speed railway based on a modified weighted l₁-norm regularization with optimal strain sensors |
| title_short |
Wheel-rail force identification for high-speed railway based on a modified weighted l₁-norm regularization with optimal strain sensors |
| title_full |
Wheel-rail force identification for high-speed railway based on a modified weighted l₁-norm regularization with optimal strain sensors |
| title_fullStr |
Wheel-rail force identification for high-speed railway based on a modified weighted l₁-norm regularization with optimal strain sensors |
| title_full_unstemmed |
Wheel-rail force identification for high-speed railway based on a modified weighted l₁-norm regularization with optimal strain sensors |
| title_sort |
wheel-rail force identification for high-speed railway based on a modified weighted l₁-norm regularization with optimal strain sensors |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/170056 |
| _version_ |
1779156656861478912 |