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Home / Journals / Proceedings of Petersburg Transport University / Volume 22 Issue 4 / Artificial Neural Network for Rotor Fault Diagnosis in an Asynchronous Traction Motor Using Magnetic Induction Parameters
Artificial Neural Network for Rotor Fault Diagnosis in an Asynchronous Traction Motor Using Magnetic Induction Parameters
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ARTIFICIAL NEURAL NETWORK FOR ROTOR FAULT DIAGNOSIS IN AN ASYNCHRONOUS TRACTION MOTOR USING MAGNETIC INDUCTION PARAMETERS
Vahidov Mirabror 1
Hamidov Otabek Rustamovich 2
Akbarova Shohsanam 3
Authors:
1.  Tashkent State Transport University (“Locomotives and Locomotive Economy” Department, Postgraduate Student)

Russian Federation
2.  Tashkent University of Transport (Professor)

3.  Tashkent State Transport University (“Locomotives and Locomotive Economy” Department, Associate Professor)

Russian Federation
Type:
Article
DOI:
https://doi.org/10.20295/1815-588X-2025-4-916-925
Pages:
from 916 to 925
Status:
Published
Received:
27.08.2025
Accepted:
08.10.2025
Published:
05.12.2025
Subject area:
UDC 629.423.31
Language:
Russian
Keywords:
Asynchronous traction motor, magnetic induction, neural network, rotor fault diagnosis, spectral analysis, Python, machine learning, technical diagnostics, CSV, predictive maintenance
Abstract and keywords
Abstract (English):
This paper presents a hybrid approach to the diagnosis of the rotor condition in an asynchronous traction motor. This approach is based on the analysis of magnetic induction parameters. Using experimental data obtained in CSV format, a model was constructed in Python environment employing an artificial neural network. Methods: In the initial phase, data preparation included numerical value standardisation and the elimination of extraneous noise. Subsequently, spectral analysis of magnetic induction signals was performed using the Fast Fourier Transform (FFT) to extract diagnostically significant frequency components. Results: The neural network architecture has been implemented using Keras and comprised two hidden layers. The model was trained on a dataset comprising 100 samples, and it has demonstrated high accuracy (up to 98%) on test data. A comparative analysis of magnetic field characteristics was carried out for defective and non-defective cases. The findings have demonstrated that the proposed approach is capable of effectively detecting rotor cracks while minimizing the necessity for complex measurement setups. Practical significance: The work has been carried out exclusively through the utilization of open-source tools.

Keywords:
Asynchronous traction motor, magnetic induction, neural network, rotor fault diagnosis, spectral analysis, Python, machine learning, technical diagnostics, CSV, predictive maintenance
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References

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