Fault Diagnosis Method of Rolling Bearing Based on 1D Multi-Channel Improved Convolutional Neural Network in Noisy Environment

Huijuan Guo; Dongzhi Ping; Lijun Wang; Weijie Zhang; Junfeng Wu; Xiao Ma; Qiang Xu; Zhongyu Lu

doi:10.3390/s25072286

Fault Diagnosis Method of Rolling Bearing Based on 1D Multi-Channel Improved Convolutional Neural Network in Noisy Environment

Huijuan Guo, Dongzhi Ping, Lijun Wang, Weijie Zhang, Junfeng Wu, Xiao Ma, Qiang Xu, Zhongyu Lu

Research output: Contribution to journal › Article › peer-review

Abstract

The vibration signal of mechanical equipment in operating environments is the key to describing fault characteristics, but due to thez influence of equipment density and environmental interference, the accuracy of fault diagnosis is often affected by noise. In this paper, a fault diagnosis method based on a 1D Multi-Channel Improved Convolutional Neural Network (1DMCICNN) is proposed. By introducing BiLSTM, an attention mechanism and a local sparse structure of a two-channel Convolutional Neural Network, the feature information of the noisy timing signal is fully extracted at different scales while reducing the computational parameters. The model is verified through experiments under different signal-to-noise ratios and loads. The results show that the accuracy of 1DMCICNN is 98.67%, 99.71%, 99.04%, and 99.71% on different load and speed datasets. Meanwhile, compared with the unoptimized two-channel Convolutional Neural Network, the training parameters are reduced by 55.58%.

Original language	English
Article number	2286
Number of pages	27
Journal	Sensors
Volume	25
Issue number	7
Early online date	4 Apr 2025
DOIs	https://doi.org/10.3390/s25072286
Publication status	Published - 4 Apr 2025

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10.3390/s25072286Licence: CC BY

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title = "Fault Diagnosis Method of Rolling Bearing Based on 1D Multi-Channel Improved Convolutional Neural Network in Noisy Environment",

abstract = "The vibration signal of mechanical equipment in operating environments is the key to describing fault characteristics, but due to thez influence of equipment density and environmental interference, the accuracy of fault diagnosis is often affected by noise. In this paper, a fault diagnosis method based on a 1D Multi-Channel Improved Convolutional Neural Network (1DMCICNN) is proposed. By introducing BiLSTM, an attention mechanism and a local sparse structure of a two-channel Convolutional Neural Network, the feature information of the noisy timing signal is fully extracted at different scales while reducing the computational parameters. The model is verified through experiments under different signal-to-noise ratios and loads. The results show that the accuracy of 1DMCICNN is 98.67%, 99.71%, 99.04%, and 99.71% on different load and speed datasets. Meanwhile, compared with the unoptimized two-channel Convolutional Neural Network, the training parameters are reduced by 55.58%.",

keywords = "Convolutional Neural Networks, deep learning, fault diagnosis, gearbox, vibration signal",

author = "Huijuan Guo and Dongzhi Ping and Lijun Wang and Weijie Zhang and Junfeng Wu and Xiao Ma and Qiang Xu and Zhongyu Lu",

note = "Funding Information: This research was supported by the \u201CZHONGYUAN Talent Program\u201D (ZYYCYU202012112), Henan Province\u2019s New Key Discipline\u2014Machinery, Foreign Expert Project of the Ministry of Science and Technology of the People\u2019s Republic of China (G2023026004L), the Water Conservancy Equipment and Intelligent Operation and Maintenance Engineering Technology Research Centre in Henan Province (Yukeshi2024-01), the Henan International Joint Laboratory of Thermo-Fluid Electro Chemical System for New Energy Vehicle (Yuke2020-23), and the Scientific and Technological Project of Henan Province (NO. 232102211035, NO. 242102240133). Publisher Copyright: {\textcopyright} 2025 by the authors.",

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doi = "10.3390/s25072286",

language = "English",

volume = "25",

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T1 - Fault Diagnosis Method of Rolling Bearing Based on 1D Multi-Channel Improved Convolutional Neural Network in Noisy Environment

AU - Guo, Huijuan

AU - Ping, Dongzhi

AU - Wang, Lijun

AU - Zhang, Weijie

AU - Wu, Junfeng

AU - Ma, Xiao

AU - Xu, Qiang

AU - Lu, Zhongyu

N1 - Funding Information: This research was supported by the \u201CZHONGYUAN Talent Program\u201D (ZYYCYU202012112), Henan Province\u2019s New Key Discipline\u2014Machinery, Foreign Expert Project of the Ministry of Science and Technology of the People\u2019s Republic of China (G2023026004L), the Water Conservancy Equipment and Intelligent Operation and Maintenance Engineering Technology Research Centre in Henan Province (Yukeshi2024-01), the Henan International Joint Laboratory of Thermo-Fluid Electro Chemical System for New Energy Vehicle (Yuke2020-23), and the Scientific and Technological Project of Henan Province (NO. 232102211035, NO. 242102240133). Publisher Copyright: © 2025 by the authors.

PY - 2025/4/4

Y1 - 2025/4/4

N2 - The vibration signal of mechanical equipment in operating environments is the key to describing fault characteristics, but due to thez influence of equipment density and environmental interference, the accuracy of fault diagnosis is often affected by noise. In this paper, a fault diagnosis method based on a 1D Multi-Channel Improved Convolutional Neural Network (1DMCICNN) is proposed. By introducing BiLSTM, an attention mechanism and a local sparse structure of a two-channel Convolutional Neural Network, the feature information of the noisy timing signal is fully extracted at different scales while reducing the computational parameters. The model is verified through experiments under different signal-to-noise ratios and loads. The results show that the accuracy of 1DMCICNN is 98.67%, 99.71%, 99.04%, and 99.71% on different load and speed datasets. Meanwhile, compared with the unoptimized two-channel Convolutional Neural Network, the training parameters are reduced by 55.58%.

AB - The vibration signal of mechanical equipment in operating environments is the key to describing fault characteristics, but due to thez influence of equipment density and environmental interference, the accuracy of fault diagnosis is often affected by noise. In this paper, a fault diagnosis method based on a 1D Multi-Channel Improved Convolutional Neural Network (1DMCICNN) is proposed. By introducing BiLSTM, an attention mechanism and a local sparse structure of a two-channel Convolutional Neural Network, the feature information of the noisy timing signal is fully extracted at different scales while reducing the computational parameters. The model is verified through experiments under different signal-to-noise ratios and loads. The results show that the accuracy of 1DMCICNN is 98.67%, 99.71%, 99.04%, and 99.71% on different load and speed datasets. Meanwhile, compared with the unoptimized two-channel Convolutional Neural Network, the training parameters are reduced by 55.58%.

KW - Convolutional Neural Networks

KW - deep learning

KW - fault diagnosis

KW - gearbox

KW - vibration signal

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VL - 25

JO - Sensors

JF - Sensors

SN - 1424-3210

IS - 7

M1 - 2286

ER -

Fault Diagnosis Method of Rolling Bearing Based on 1D Multi-Channel Improved Convolutional Neural Network in Noisy Environment

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