Abstract
A major issue of machinery fault diagnosis using vibration signals is that it is over-reliant on personnel knowledge and experience in interpreting the signal. Thus, machine learning has been adapted for machinery fault diagnosis. The quantity and quality of the input features, however, influence the fault classification performance. Feature selection plays a vital role in selecting the most representative feature subset for the machine learning algorithm. In contrast, the trade-off relationship between capability when selecting the best feature subset and computational effort is inevitable in the wrapper-based feature selection (WFS) method. This paper proposes an improved WFS technique before integration with a support vector machine (SVM) model classifier as a complete fault diagnosis system for a rolling element bearing case study. The bearing vibration dataset made available by the Case Western Reserve University Bearing Data Centre was executed using the proposed WFS and its performance has been analysed and discussed. The results reveal that the proposed WFS secures the best feature subset with a lower computational effort by eliminating the redundancy of re-evaluation. The proposed WFS has therefore been found to be capable and efficient to carry out feature selection tasks.
Highlights
Condition monitoring and fault diagnosis is essential for a wide range of mechanical components to ensure optimal performance
The aim of this study was to improve the capability of the wrapper-based feature selection (WFS) method for selecting the best feature subset with a reduced computational effort
The analysis of the results revealed that the proposed WFS is capable of selecting the most representative feature subset for the bearing dataset
Summary
Condition monitoring and fault diagnosis is essential for a wide range of mechanical components to ensure optimal performance. Vibration signal analysis has been proven to be the most effective method for rotating machinery fault diagnosis. There has been increasing interest in automated machinery fault diagnosis through the adaptive machine learning approach. This provides a more consistent diagnostic outcome; the quantity and quality of the input features have a great influence on the fault diagnostic performance. The complexity of the features that have been extracted from a continuous vibration signal leads to the capability of the features remaining unknown, resulting in unconvincing information conversion and representativeness for various conditions, stages or intermediate cycles [2,3,4,5,6].
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