A gear fault diagnosis method based on auditory cortical frequency-domain response in real workshop noise environment

Abstract

Acoustic-based diagnosis (ABD) has become a research hotspot in gear fault diagnosis due to its noncontact advantage. Interference from ambient noise is one of the critical problems that urgently need to be solved in the practical application of ABD methods. The human auditory system has a strong ability to resist noise, with the auditory cortex playing a core role. Therefore, a gear fault diagnosis method based on auditory cortex frequency-domain response under real workshop noise conditions is proposed in this paper. This method simulates the auditory cortex processing mechanism, calculates the auditory cortical frequency-domain responses of gear sound signals containing workshop noise, and thereby obtains the noise-resistant processed data. Subsequently, the auditory cortical frequency-domain responses are clustered and subjected to dimensionality reduction through cross-correlation analysis, and appropriate features are extracted from the dimensionally reduced data to form a feature vector set. Finally, the classification part is implemented by the support vector machine. The classification results indicate that an average accuracy of 99.26% under different signal-to-noise ratio conditions can be achieved by this method, which shows better diagnostic outcomes compared with existing methods. This method can provide a new idea for gear fault diagnosis in noisy environments.

Keywords

Acoustic-based gear fault diagnosis auditory cortical frequency-domain response feature extraction support vector machine

Get full access to this article

View all access options for this article.

References

Pan

Ding

Qiao

, et al. Metamaterial-based acoustic enhanced sensing for gearbox weak fault fault feature diagnosis. Smart Mater Struct 2023; 32: 105034.

Huang

Lin

Tang

, et al. Sensing with sound enhanced acoustic metamaterials for fault diagnosis. Front Phys 2022; 10: 1027895.

Wang

Xie

, et al. A portable industrial acoustic detection system with multiband resonant amplification. IEEE Trans Instrum Meas 2023; 72: 1–9.

del Rosario Bautista-Morales

Patiño-López

. Acoustic detection of bearing faults through fractional harmonics lock-in amplification. Mech Syst Signal Process 2023; 185: 109740.

Shuai

Junxia

Lei

, et al. Research on acoustic fault diagnosis of bearings based on spatial filtering and time-frequency domain filtering. Measurement 2023; 221: 113533.

Yao

Liu

Song

, et al. Fault diagnosis of planetary gearbox based on acoustic signals. Appl Acoust 2021; 181: 108151.

Qin

Wang

, et al. Improved empirical wavelet transform for compound weak bearing fault diagnosis with acoustic signals. Appl Sci 2020; 10: 682.

Yao

Gui

Yang

, et al. An adaptive anti-noise network with recursive attention mechanism for gear fault diagnosis in real-industrial noise environment condition. Measurement 2021; 186: 110169.

Yao

Gui

Yang

, et al. A recursive denoising learning for gear fault diagnosis based on acoustic signal in real industrial noise condition. IEEE Trans Instrum Meas 2021; 70: 1–15.

10.

Yao

Gui

Yang

, et al. A recursive multi-head self-attention learning for acoustic-based gear fault diagnosis in real-industrial noise condition. Eng Appl Artif Intell 2024; 133: 108240.

11.

Liu

Wang

, et al. Mechanical fault diagnosis of gas-insulated switchgear based on saliency feature of auditory brainstem response under noise background. Meas Sci Technol 2024; 35: 015008.

12.

Yaman

Yol

Altinors

A fault detection method based on embedded feature extraction and SVM classification for UAV motors. Microprocess Microsyst 2022; 94: 104683.

13.

Santosa

Hong

. Separation of the hemodynamic responses in a simultaneous audio-stimuli using ICA: an fNIRS study. In: 2015 15th International conference on control, automation and systems (ICCAS), Busan, Korea, 13–16 Oct 2015, pp. 1822–1826. IEEE.

14.

Girolami

A nonlinear model of the binaural cocktail party effect. Neurocomputing 1998; 22: 201–215.

15.

Zhao

Yang

Liu

, et al. Hierarchical spiking neural network auditory feature based dry-type transformer fault diagnosis using convolutional neural network. Meas Sci Technol 2024; 35: 036104.

16.

Yao

Wang

, et al. End-to-end convolutional neural network model for gear fault diagnosis based on sound signals. Appl Sci 2018; 8: 1584.

17.

Liu

Cheng

, et al. Sound absorption of several various nickel foam multilayer structures at aural frequencies sensitive for human ears. Trans Nonferrous Met Soc China 2018; 28: 1334–1341.

18.

Varga

Steeneken

HJM

. Assessment for automatic speech recognition: II. NOISEX-92: a database and an experiment to study the effect of additive noise on speech recognition systems. Speech Commun 1993; 12: 247–251.

19.

Zhao

Shi

Tan

, et al. Research on an intelligent diagnosis method of mechanical faults for small sample data sets. Sci Rep 2022; 12: 21996.

20.

McKeown

Patterson

RD.

The time course of auditory segregation: concurrent vowels that vary in duration. J Acoust Soc Am 1995; 98: 1866–1877.

21.

Yang

Jiang

Liu

, et al. A realtime analysis/synthesis Gammatone filterbank. In: 2015 IEEE international conference on signal processing, communications and computing (ICSPCC), Ningbo, China, 19–22 Sep 2015, pp. 1–6. Piscataway, NJ: IEEE.

22.

Meddis

Simulation of mechanical to neural transduction in the auditory receptor. J Acoust Soc Am 1986; 79(3): 702–711.

23.

Meddis

Simulation of auditory-neural transduction: further studies. J Acoust Soc Am 1988; 83(3): 1056–1063.

24.

Shamma

Encoding sound timbre in the auditory system. IETE J Res 2003; 49: 145–156.

25.

Yang

Chen

A perceptual space for underwater man-made sounds towards target classification. Appl Acoust 2016; 110: 119–127.

26.

Wang

Shamma

SA.

Spectral shape analysis in the central auditory system. IEEE Trans Speech Audio Process 1995; 3: 382–395.

27.

Huang

H-L

Chang

F-L.

ESVM: evolutionary support vector machine for automatic feature selection and classification of microarray data. Biosystems 2007; 90: 516–528.

28.

Cortes

Vapnik

Support-vector networks. Mach Learn 1995; 20: 273–297.

29.

Cherkassky

The nature of statistical learning theory. IEEE Trans Neural Netw 1997; 8(6): 1564–1564.

30.

Jung

Kim

S-H

Yun

S-H

, et al. Vibration, acoustic, temperature, and motor current dataset of rotating machine under varying operating conditions for fault diagnosis. Data Brief 2023; 48: 109049.