A Multimodal Lightweight Approach to Fault Diagnosis of Induction Motors in High-Dimensional Dataset

TL;DR

This paper presents a lightweight, transfer-learning-based deep learning approach using ShuffleNetV2 and spectral imaging for accurate, efficient fault diagnosis of induction motors with multiple broken rotor bars in large datasets.

Contribution

It introduces a novel application of ShuffleNetV2 with spectral images for large-scale fault diagnosis, addressing overfitting issues in industrial environments.

Findings

Achieved 98.856% accuracy in classifying spectral images.

Demonstrated reduced computational cost with ShuffleNetV2.

Provided detailed analysis of training and testing times.

Abstract

An accurate AI-based diagnostic system for induction motors (IMs) holds the potential to enhance proactive maintenance, mitigating unplanned downtime and curbing overall maintenance costs within an industrial environment. Notably, among the prevalent faults in IMs, a Broken Rotor Bar (BRB) fault is frequently encountered. Researchers have proposed various fault diagnosis approaches using signal processing (SP), machine learning (ML), deep learning (DL), and hybrid architectures for BRB faults. One limitation in the existing literature is the training of these architectures on relatively small datasets, risking overfitting when implementing such systems in industrial environments. This paper addresses this limitation by implementing large-scale data of BRB faults by using a transfer-learning-based lightweight DL model named ShuffleNetV2 for diagnosing one, two, three, and four BRB faults using current and vibration signal data. Spectral images for training and testing are generated using a Short-Time Fourier Transform (STFT). The dataset comprises 57,500 images, with 47,500 used for training and 10,000 for testing. Remarkably, the ShuffleNetV2 model exhibited superior performance, in less computational cost as well as accurately classifying 98.856% of spectral images. To further enhance the visualization of harmonic sidebands resulting from broken bars, Fast Fourier Transform (FFT) is applied to current and vibration data. The paper also provides insights into the training and testing times for each model, contributing to a comprehensive understanding of the proposed fault diagnosis methodology. The findings of our research provide valuable insights into the performance and efficiency of different ML and DL models, offering a foundation for the development of robust fault diagnosis systems for induction motors in industrial settings.