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Multiple Convolutional Recurrent Neural Networks for Fault Identification and Performance Degradation Evaluation of High-Speed Train Bogie | IEEE Journals & Magazine | IEEE Xplore
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Journals & Magazines >IEEE Transactions on Neural N... >Volume: 31 Issue: 12

Multiple Convolutional Recurrent Neural Networks for Fault Identification and Performance Degradation Evaluation of High-Speed Train Bogie

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Na Qin; Kaiwei Liang; Deqing Huang; Lei Ma; Andrew H. Kemp
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Abstract:

As an important part of high-speed train (HST), the mechanical performance of bogies imposes a direct impact on the safety and reliability of HST. It is a fact that, rega...Show More

Metadata

Abstract:

As an important part of high-speed train (HST), the mechanical performance of bogies imposes a direct impact on the safety and reliability of HST. It is a fact that, regardless of the potential mechanical performance degradation status, most existing fault diagnosis methods focus only on the identification of bogie fault types. However, for application scenarios such as auxiliary maintenance, identifying the performance degradation of bogie is critical in determining a particular maintenance strategy. In this article, by considering the intrinsic link between fault type and performance degradation of bogie, a novel multiple convolutional recurrent neural network (M-CRNN) that consists of two CRNN frameworks is proposed for simultaneous diagnosis of fault type and performance degradation state. Specifically, the CRNN framework 1 is designed to detect the fault types of the bogie. Meanwhile, CRNN framework 2, which is formed by CRNN Framework 1 and an RNN module, is adopted to further extract the features of fault performance degradation. It is worth highlighting that M-CRNN extends the structure of traditional neural networks and makes full use of the temporal correlation of performance degradation and model fault types. The effectiveness of the proposed M-CRNN algorithm is tested via the HST model CRH380A at different running speeds, including 160, 200, and 220 km/h. The overall accuracy of M-CRNN, i.e., the product of the accuracies for identifying the fault types and evaluating the fault performance degradation, is beyond 94.6% in all cases. This clearly demonstrates the potential applicability of the proposed method for multiple fault diagnosis tasks of HST bogie system.
Published in: IEEE Transactions on Neural Networks and Learning Systems ( Volume: 31, Issue: 12, December 2020)
Page(s): 5363 - 5376
Date of Publication: 10 February 2020

ISSN Information:

PubMed ID: 32054588
DOI: 10.1109/TNNLS.2020.2966744

Funding Agency:

References is not available for this document.
Contents

I. Introduction

The growing complexity of high-speed train (HST) system poses plenty of challenges to its fault diagnosis. In order to ensure the availability and reliability of the railway network, it is important to recognize the status of the train in operation [1]–[5].

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