Artificial neural network–based fault diagnosis for induction motors under similar, interpolated and extrapolated operating conditions

Chouhan, Abhisar; Gangsar, Purushottam; Porwal, Rajkumar; Mechefske, Christopher

doi:10.1177/09574565211030709

Cited by 15 publications

(2 citation statements)

References 37 publications

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“…A. Chouhan et al (2021) have developed an effective Artificial Neural Network (ANN) model for predicting both electrical and mechanical faults in an induction motor, which is operated at three different conditions: same speed, interpolated speed and extrapolated speed. A machinery fault stimulator is utilized to measure the current and vibration signals of healthy and faulty induction motors.…”

Section: Related Workmentioning

confidence: 99%

Regression Based Performance Analysis and Fault Detection in Induction Motors by Using Deep Learning Technique

Katta¹,

Kandasamy²,

Raja³

et al. 2023

ADCAIJ

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The recent improvements related to the area of electric locomotive, power electronics, assembly processes and manufacturing of machines have increased the robustness and reliability of induction motors. Regardless of the increased availability, the application of induction motors in many fields alleges the need for operating state supervision and condition monitoring. In other words, fault identification at the initial stage helps make appropriate control decisions, influencing product quality as well as providing safety. Inspired by these demands, this work proposes a regression based modeling for the analysis of performance in induction motors. In this approach, the feature extraction process is combined with classification for efficient fault detection. Deep Belief Network (DBN) stacked with multiple Restricted Boltzmann Machine (RBM) is exploited for the robust diagnosis of faults with the adoption of training process. The influences of harmonics over induction motors are identified and the losses are mitigated. The simulation of the suggested approach and its comparison with traditional approaches are executed. An overall accuracy of 99.5% is obtained which in turn proves the efficiency of DBN in detecting faults.

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Section: Related Workmentioning

confidence: 99%

Regression Based Performance Analysis and Fault Detection in Induction Motors by Using Deep Learning Technique

Katta¹,

Kandasamy²,

Raja³

et al. 2023

ADCAIJ

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“…Conversely, the authors determined only on rolling bearing failures. Many existing methods have used the ANN and SVM (Support Vector Machine) classifier for the induction motor fault classification [13][14][15]. Agrawal and Jayaswal [16] proposed a comparative analysis between SVM and ANN by applying the energy entropy models and the continuous wavelet transforms to detect and classify the rolling component bearings.…”

Section: Introductionmentioning

confidence: 99%

Induction Motor Fault Detection and Classification using RCNN and SURF Based Machine Learning Algorithms and Infrared Thermography

Sasikumar,

Venkatasalam,

Rajendran

2024

Scientia Iranica

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Induction motors in electrical industries face stress and potential faults. Preventive maintenance, including fault detection, is vital for safety and energy conservation. Infrared imaging, though underutilized, can monitor machine conditions effectively. In response to this gap, this paper presents a novel motor fault identification method employing infrared thermography (IRT) in combination with image processing and machine learning techniques, with a particular focus on energy efficiency. IRT is harnessed for early fault detection to promote energy conservation. The approach involves the extraction of color and texture features from the motor's infrared images using the Gabor filter and GNS (Global Neighbourhood Structure) map. The proposed method integrates the faster R-CNN (Region-based Convolutional NeuralNetwork) with the SURF (Speeded Up Robust Features) algorithm to enhance fault detection and classification accuracy. SURF serves as a feature descriptor for faster R-CNN, enabling object detection and fault classification based on the extracted features. Additionally, efficiency is assessed using the Finite Element Method (FEM) based on stator and rotor power, contributing to energy conservation through early fault detection in motors. Notably, the proposed motor fault classification is applicable under various loading conditions, consistently achieving accuracy rates exceeding 90%.

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Rolling element bearing fault diagnosis using supervised learning methods- artificial neural network and discriminant classifier

Gundewar

Kane

2022

Int J Syst Assur Eng Manag

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Artificial neural network–based fault diagnosis for induction motors under similar, interpolated and extrapolated operating conditions

Cited by 15 publications

References 37 publications

Regression Based Performance Analysis and Fault Detection in Induction Motors by Using Deep Learning Technique

Regression Based Performance Analysis and Fault Detection in Induction Motors by Using Deep Learning Technique

Induction Motor Fault Detection and Classification using RCNN and SURF Based Machine Learning Algorithms and Infrared Thermography

Rolling element bearing fault diagnosis using supervised learning methods- artificial neural network and discriminant classifier

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