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A generalised machine learning model based on multi-nomial logistic regression and frequency features for rolling bearing fault classification

A generalised machine learning model based on multi-nomial logistic regression and frequency features for rolling bearing fault classification
A generalised machine learning model based on multi-nomial logistic regression and frequency features for rolling bearing fault classification
Intelligent fault classification of rolling element bearings (REBs) using machine learning (ML) techniques increases the reliability of industrial assets. One of the main issues associated with ML model development is the lack of training data and most importantly the ability of models to be used for applications without specific training data, i.e., generalization capability of models. This study investigates the feasibility of using multinomial logistic regression (MLR) as generalised ML models for rolling element bearing fault classification without the requirement of training data for new bearing designs and varied machine operations. This has been achieved by using bearing characteristic frequencies (BCFs) as inputs to the MLR models extracted by a newly developed hybrid method. The new method combines cepstrum pre-whitening (CPW) and full-band enveloping , which can effectively identify the BCFs in vibration data from various machines. This paper presents the methods of the feature extraction and the development of generalised ML models for REBs based on data from EU Clean Sky2 I2BS project1. This model is then validated by data from Case Western Reserve University (CWRU) and US Society for Machinery Failure Prevention Technology (MFPT) available in the public domain without further training.
rolling element bearings, Intelligent fault classification, bearing characteristic frequencies, multinomial logistic regression, generalized machine learning model
447-452
Kiakojouri, Amirmasoud
2a451714-d4fa-4ecc-9775-e828e975c884
Lu, Zudi
4aa7d988-ac2b-4150-a586-ca92b8adda95
Mirring, Patrick
7f50dd2b-912e-4994-aa2b-2a75befcc2cf
Powrie, Honor
81067bac-f71e-4bdb-b216-87f4f4da43de
Wang, Ling
c50767b1-7474-4094-9b06-4fe64e9fe362
Kiakojouri, Amirmasoud
2a451714-d4fa-4ecc-9775-e828e975c884
Lu, Zudi
4aa7d988-ac2b-4150-a586-ca92b8adda95
Mirring, Patrick
7f50dd2b-912e-4994-aa2b-2a75befcc2cf
Powrie, Honor
81067bac-f71e-4bdb-b216-87f4f4da43de
Wang, Ling
c50767b1-7474-4094-9b06-4fe64e9fe362

Kiakojouri, Amirmasoud, Lu, Zudi, Mirring, Patrick, Powrie, Honor and Wang, Ling (2022) A generalised machine learning model based on multi-nomial logistic regression and frequency features for rolling bearing fault classification. The Eighteenth International Conference on Condition Monitoring and Asset Management, Radisson Hotel and Conference Centre, London, United Kingdom. 07 - 09 Jun 2022. pp. 447-452 .

Record type: Conference or Workshop Item (Paper)

Abstract

Intelligent fault classification of rolling element bearings (REBs) using machine learning (ML) techniques increases the reliability of industrial assets. One of the main issues associated with ML model development is the lack of training data and most importantly the ability of models to be used for applications without specific training data, i.e., generalization capability of models. This study investigates the feasibility of using multinomial logistic regression (MLR) as generalised ML models for rolling element bearing fault classification without the requirement of training data for new bearing designs and varied machine operations. This has been achieved by using bearing characteristic frequencies (BCFs) as inputs to the MLR models extracted by a newly developed hybrid method. The new method combines cepstrum pre-whitening (CPW) and full-band enveloping , which can effectively identify the BCFs in vibration data from various machines. This paper presents the methods of the feature extraction and the development of generalised ML models for REBs based on data from EU Clean Sky2 I2BS project1. This model is then validated by data from Case Western Reserve University (CWRU) and US Society for Machinery Failure Prevention Technology (MFPT) available in the public domain without further training.

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Published date: 1 August 2022
Venue - Dates: The Eighteenth International Conference on Condition Monitoring and Asset Management, Radisson Hotel and Conference Centre, London, United Kingdom, 2022-06-07 - 2022-06-09
Keywords: rolling element bearings, Intelligent fault classification, bearing characteristic frequencies, multinomial logistic regression, generalized machine learning model

Identifiers

Local EPrints ID: 468912
URI: http://eprints.soton.ac.uk/id/eprint/468912
PURE UUID: 1854676b-5cf0-48eb-bddf-ec8d6d6ffd5b
ORCID for Amirmasoud Kiakojouri: ORCID iD orcid.org/0000-0001-5978-1970
ORCID for Zudi Lu: ORCID iD orcid.org/0000-0003-0893-832X
ORCID for Ling Wang: ORCID iD orcid.org/0000-0002-2894-6784

Catalogue record

Date deposited: 01 Sep 2022 16:39
Last modified: 17 Mar 2024 04:04

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Contributors

Author: Amirmasoud Kiakojouri ORCID iD
Author: Zudi Lu ORCID iD
Author: Patrick Mirring
Author: Honor Powrie
Author: Ling Wang ORCID iD

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