Intelligent fault diagnosis of rolling bearings based on LSTM with large margin nearest neighbor algorithm

Intelligent fault diagnosis of rolling bearings based on LSTM with large margin nearest neighbor algorithm

In industrial machinery, rolling bearings are often rated as the most likely to fail in mechanical systems due to excessive working stress. Therefore, effective methods to diagnose the faults in rolling bearings are becoming necessary and required to ensure economic efficiency and manufacturing reli...

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Veröffentlicht in:Neural computing & applications 2022-11, Vol.34 (22), p.19401-19421
Hauptverfasser: Aljemely, Anas H., Xuan, Jianping, Al-Azzawi, Osama, Jawad, Farqad K. J.
Format: Artikel
Sprache:eng
Schlagworte:
Algorithms
Artificial Intelligence
Biomedical
Computational Biology/Bioinformatics
Computational Science and Engineering
Computer Science
Concept Analysis
Data collection
Data Mining and Knowledge Discovery
Deep learning
Fault diagnosis
Faults
Finance
Image analysis
Image Processing and Computer Vision
Machine learning
Mechanical systems
Probability and Statistics in Computer Science
Recommendation
Reliability
Roller bearings
Rotating machinery
Rotating machines
S.I.: Deep learning modelling in real life: (Anomaly Detection
Signal processing
Special Issue on Deep Learning Modeling in Real Life: (Anomaly Detection
System effectiveness
Vibration measurement
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container_end_page 19421
container_issue 22
container_start_page 19401
container_title Neural computing & applications
container_volume 34
creator Aljemely, Anas H.
Xuan, Jianping
Al-Azzawi, Osama
Jawad, Farqad K. J.
description In industrial machinery, rolling bearings are often rated as the most likely to fail in mechanical systems due to excessive working stress. Therefore, effective methods to diagnose the faults in rolling bearings are becoming necessary and required to ensure economic efficiency and manufacturing reliability. Recently, several studies tried to develop deep learning models for intelligent fault diagnosis based on traditional methods. However, creating an effective method for fault recognition is still a major obstacle due to varying operating conditions, large amount of collected data and redundant noise in measured vibration signals. Advanced signal processing techniques and traditional strategies often consist of shallow constructs that suffer from learning a huge amount of data, losing valuable fault information, yielding in low accuracy and labor time losses. In this paper, a combination method of long short-term memory with large margin nearest neighbor (LSTM-LMNN) is designed to address the above issues and effectively recognize multi-faults in mechanical rotating machines. Different from traditional LSTMs, the proposed LSTM-LMNN utilizes a powerful orthogonal weight initialization technique to memorize the critical information of faults during parameters updating and strongly organizing the samples of each condition in pattern classification process. Two experimental studies of bearing fault diagnosis demonstrate that the proposed LSTM-LMNN model outperformed other existing methods in terms of diagnostic efficiency, stability, and reliability.
doi_str_mv 10.1007/s00521-022-07353-8
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source SpringerLink Journals
subjects Algorithms
Artificial Intelligence
Biomedical
Computational Biology/Bioinformatics
Computational Science and Engineering
Computer Science
Concept Analysis
Data collection
Data Mining and Knowledge Discovery
Deep learning
Fault diagnosis
Faults
Finance
Image analysis
Image Processing and Computer Vision
Machine learning
Mechanical systems
Probability and Statistics in Computer Science
Recommendation
Reliability
Roller bearings
Rotating machinery
Rotating machines
S.I.: Deep learning modelling in real life: (Anomaly Detection
Signal processing
Special Issue on Deep Learning Modeling in Real Life: (Anomaly Detection
System effectiveness
Vibration measurement
title Intelligent fault diagnosis of rolling bearings based on LSTM with large margin nearest neighbor algorithm
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