On-board identification of wheel polygonization of metro trains based on convolutional neural network regression analysis and angular-domain synchronous averaging
On-board identification of wheel polygonization of metro trains based on convolutional neural network regression analysis and angular-domain synchronous averaging
Wheel polygonization, a form of wheel out-of-roundness, has become a common problem on trains of urban rail transit systems in recent years. It results in a significant increase of the dynamic responses of both the vehicle and the track, high vibration and noise levels, and structural fatigue. This paper proposes an innovative method for identifying wheel polygonization orders and their effective values using convolutional neural network (CNN) regression analysis. First, the acceleration signal measured on the axle box has been processed with the angular-domain synchronous averaging (ADSA) method, effectively separating the characteristic information associated with wheel polygonization within the signal. To extract comprehensive wheel polygonization information, a feature fusion method is employed, integrating features from both the time and frequency domain. Then, a CNN regression model is established and trained, with validation conducted using measured data of vehicle vibration and the wheel polygonization measured during field tests. Comparative analysis with different identification methods is performed, including a comparison of different preprocessing methods and machine learning models, which demonstrates the effectiveness of the proposed method in this study. The verification results show that the proposed method achieves high identification accuracy for wheel polygonization up to the 25th order. The overall average root mean square error value is 2.0 dB. Finally, the influence of wheel polygonization conditions, track stiffness, and speed fluctuation on the identification accuracy is discussed. The results show the proposed method exhibits robust identification capacity under varying conditions, which indicates its wide application and accuracy in complex situations during train service. This research contributes to advancing the field of wheel polygonization detection, offering a reliable and effective solution for application in railway systems.
Angular-domain synchronous averaging (ADSA), Axle box acceleration (ABA), Convolutional neural network (CNN), Rail vehicle, Wheel polygonization level
Sun, Wenjing
697ae912-77f1-43f4-b7ee-38cf7fb986b2
Geng, Xuan
4ea3884a-7f0e-4675-a3f9-5b05016601b5
Thompson, David J.
bca37fd3-d692-4779-b663-5916b01edae5
Wang, Tengfei
eb3cd689-e898-4751-b438-465a58062d4e
Zhou, Jinsong
5302ef52-fd22-4b4d-baa6-3c640dd17f17
Zhang, Jin
6f92519d-9a26-46e5-bfe8-70734b9c5a8f
19 March 2025
Sun, Wenjing
697ae912-77f1-43f4-b7ee-38cf7fb986b2
Geng, Xuan
4ea3884a-7f0e-4675-a3f9-5b05016601b5
Thompson, David J.
bca37fd3-d692-4779-b663-5916b01edae5
Wang, Tengfei
eb3cd689-e898-4751-b438-465a58062d4e
Zhou, Jinsong
5302ef52-fd22-4b4d-baa6-3c640dd17f17
Zhang, Jin
6f92519d-9a26-46e5-bfe8-70734b9c5a8f
Sun, Wenjing, Geng, Xuan, Thompson, David J., Wang, Tengfei, Zhou, Jinsong and Zhang, Jin
(2025)
On-board identification of wheel polygonization of metro trains based on convolutional neural network regression analysis and angular-domain synchronous averaging.
Mechanical Systems and Signal Processing, 230, [112587].
(doi:10.1016/j.ymssp.2025.112587).
Abstract
Wheel polygonization, a form of wheel out-of-roundness, has become a common problem on trains of urban rail transit systems in recent years. It results in a significant increase of the dynamic responses of both the vehicle and the track, high vibration and noise levels, and structural fatigue. This paper proposes an innovative method for identifying wheel polygonization orders and their effective values using convolutional neural network (CNN) regression analysis. First, the acceleration signal measured on the axle box has been processed with the angular-domain synchronous averaging (ADSA) method, effectively separating the characteristic information associated with wheel polygonization within the signal. To extract comprehensive wheel polygonization information, a feature fusion method is employed, integrating features from both the time and frequency domain. Then, a CNN regression model is established and trained, with validation conducted using measured data of vehicle vibration and the wheel polygonization measured during field tests. Comparative analysis with different identification methods is performed, including a comparison of different preprocessing methods and machine learning models, which demonstrates the effectiveness of the proposed method in this study. The verification results show that the proposed method achieves high identification accuracy for wheel polygonization up to the 25th order. The overall average root mean square error value is 2.0 dB. Finally, the influence of wheel polygonization conditions, track stiffness, and speed fluctuation on the identification accuracy is discussed. The results show the proposed method exhibits robust identification capacity under varying conditions, which indicates its wide application and accuracy in complex situations during train service. This research contributes to advancing the field of wheel polygonization detection, offering a reliable and effective solution for application in railway systems.
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MSSP24-624-accepted
- Accepted Manuscript
Text
1-s2.0-S0888327025002882-main
- Version of Record
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Accepted/In Press date: 13 March 2025
e-pub ahead of print date: 19 March 2025
Published date: 19 March 2025
Keywords:
Angular-domain synchronous averaging (ADSA), Axle box acceleration (ABA), Convolutional neural network (CNN), Rail vehicle, Wheel polygonization level
Identifiers
Local EPrints ID: 500320
URI: http://eprints.soton.ac.uk/id/eprint/500320
ISSN: 0888-3270
PURE UUID: 780cfe99-5651-49b2-a23e-494ef1ba5862
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Date deposited: 25 Apr 2025 16:31
Last modified: 30 Aug 2025 01:36
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Contributors
Author:
Wenjing Sun
Author:
Xuan Geng
Author:
Tengfei Wang
Author:
Jinsong Zhou
Author:
Jin Zhang
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