Vibration Signal for Bearing Fault Detection using Random Forest

Based on the chosen properties of an induction motor, a random forest (RF) classifier, a machine learning technique, is examined in this study for bearing failure detection. A time-varying actual dataset with four distinct bearing states was used to evaluate the suggested methodology. The primary ob...

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Main Authors: Abedin T., Koh S.P., Yaw C.T., Phing C.C., Tiong S.K., Tan J.D., Ali K., Kadirgama K., Benedict F.
Other Authors: 57226667845
Format: Conference Paper
Published: Institute of Physics 2024
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spelling my.uniten.dspace-345812024-10-14T11:20:50Z Vibration Signal for Bearing Fault Detection using Random Forest Abedin T. Koh S.P. Yaw C.T. Phing C.C. Tiong S.K. Tan J.D. Ali K. Kadirgama K. Benedict F. 57226667845 22951210700 36560884300 57884999200 15128307800 38863172300 36130958600 12761486500 57194591957 Bearing Fault Detection Principal Component Analysis Random Forest Classification (of information) Fault detection Forestry Induction motors Learning systems Vibration analysis Bearing Bearing fault detection Data frames Faults detection Outer races Principal-component analysis Property Random forest classifier Random forests Vibration signal Principal component analysis Based on the chosen properties of an induction motor, a random forest (RF) classifier, a machine learning technique, is examined in this study for bearing failure detection. A time-varying actual dataset with four distinct bearing states was used to evaluate the suggested methodology. The primary objective of this research is to evaluate the bearing defect detection accuracy of the RF classifier. First, run four loops that cycle over each feature of the data frame corresponding to the daytime index to determine the bearing states. There were 465 repetitions of the inner race fault and the roller element fault in test 1, 218 repetitions of the outer race fault in test 2, and 6324 repetitions of the outer race in test 3. Secondly, the task is to find the data for the typical bearing data procedure to differentiate between normal and erroneous data. Out of 3 tests, (22-23) % normal data was obtained since every bearing beginning to degrade usually exhibits some form of a spike in many locations, or the bearing is not operating at its optimum speed. Thirdly, to display and comprehend the data in a 2D and 3D environment, Principal Component Analysis (PCA) is performed. Fourth, the RF algorithm classifier recognized the data frame's actual predictions, which were 99% correct for normal bearings, 97% accurate for outer races, 94% accurate for inner races, and 97% accurate for roller element faults. It is thus concluded that the proposed algorithm is capable to identify the bearing faults. � Published under licence by IOP Publishing Ltd. Final 2024-10-14T03:20:50Z 2024-10-14T03:20:50Z 2023 Conference Paper 10.1088/1742-6596/2467/1/012017 2-s2.0-85160519158 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85160519158&doi=10.1088%2f1742-6596%2f2467%2f1%2f012017&partnerID=40&md5=0702bee41810d14a0328d1e0d220b38b https://irepository.uniten.edu.my/handle/123456789/34581 2467 1 12017 All Open Access Gold Open Access Institute of Physics Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Bearing
Fault Detection
Principal Component Analysis
Random Forest
Classification (of information)
Fault detection
Forestry
Induction motors
Learning systems
Vibration analysis
Bearing
Bearing fault detection
Data frames
Faults detection
Outer races
Principal-component analysis
Property
Random forest classifier
Random forests
Vibration signal
Principal component analysis
spellingShingle Bearing
Fault Detection
Principal Component Analysis
Random Forest
Classification (of information)
Fault detection
Forestry
Induction motors
Learning systems
Vibration analysis
Bearing
Bearing fault detection
Data frames
Faults detection
Outer races
Principal-component analysis
Property
Random forest classifier
Random forests
Vibration signal
Principal component analysis
Abedin T.
Koh S.P.
Yaw C.T.
Phing C.C.
Tiong S.K.
Tan J.D.
Ali K.
Kadirgama K.
Benedict F.
Vibration Signal for Bearing Fault Detection using Random Forest
description Based on the chosen properties of an induction motor, a random forest (RF) classifier, a machine learning technique, is examined in this study for bearing failure detection. A time-varying actual dataset with four distinct bearing states was used to evaluate the suggested methodology. The primary objective of this research is to evaluate the bearing defect detection accuracy of the RF classifier. First, run four loops that cycle over each feature of the data frame corresponding to the daytime index to determine the bearing states. There were 465 repetitions of the inner race fault and the roller element fault in test 1, 218 repetitions of the outer race fault in test 2, and 6324 repetitions of the outer race in test 3. Secondly, the task is to find the data for the typical bearing data procedure to differentiate between normal and erroneous data. Out of 3 tests, (22-23) % normal data was obtained since every bearing beginning to degrade usually exhibits some form of a spike in many locations, or the bearing is not operating at its optimum speed. Thirdly, to display and comprehend the data in a 2D and 3D environment, Principal Component Analysis (PCA) is performed. Fourth, the RF algorithm classifier recognized the data frame's actual predictions, which were 99% correct for normal bearings, 97% accurate for outer races, 94% accurate for inner races, and 97% accurate for roller element faults. It is thus concluded that the proposed algorithm is capable to identify the bearing faults. � Published under licence by IOP Publishing Ltd.
author2 57226667845
author_facet 57226667845
Abedin T.
Koh S.P.
Yaw C.T.
Phing C.C.
Tiong S.K.
Tan J.D.
Ali K.
Kadirgama K.
Benedict F.
format Conference Paper
author Abedin T.
Koh S.P.
Yaw C.T.
Phing C.C.
Tiong S.K.
Tan J.D.
Ali K.
Kadirgama K.
Benedict F.
author_sort Abedin T.
title Vibration Signal for Bearing Fault Detection using Random Forest
title_short Vibration Signal for Bearing Fault Detection using Random Forest
title_full Vibration Signal for Bearing Fault Detection using Random Forest
title_fullStr Vibration Signal for Bearing Fault Detection using Random Forest
title_full_unstemmed Vibration Signal for Bearing Fault Detection using Random Forest
title_sort vibration signal for bearing fault detection using random forest
publisher Institute of Physics
publishDate 2024
_version_ 1814060104827273216
score 13.222552