TY - GEN
T1 - Improved Residual Network and LSTM Hybrid Model Based Tool Health Monitoring
AU - Bian, Qingchao
AU - Wang, Cunsong
AU - Bo, Cuimei
AU - Peng, Hao
N1 - Publisher Copyright:
© 2023 IEEE.
PY - 2023
Y1 - 2023
N2 - Health monitoring is crucial for intelligent manufacturing systems to reduce downtime, avoid major hazardous accidents, improve work efficiency, and save costs. The current mainstream health monitoring methods, such as CNN and LSTM, donot consider sequence and time dependencies together. To solve the above problem, an improved residual network and LSTM hybrid model based tool health monitoring is proposed in this paper. First, in the experiment, Wavelet transform was employed as the initial step for time series reconstruction, with the aim of achieving both dimensionality reduction and denoising. The resulting reconstructed time data was fed into the enhanced hybrid model. Then, the improved hybrid model overcomes the shortcomings of the single model, and avoids the mutual interference problem of the conventional combination model in feature extraction. Finally, hybrid model utilizes parallel Deep Residual Networks (DRN) and Long Short- Term Memory (LSTM) networks to extract high-dimensional features from the data. These extracted features are subsequently fed into the fully connected layer via an attention mechanism module to yield the predicted results. The universality and accuracy of the method in the paper were verified through the PHM20 10 dataset.
AB - Health monitoring is crucial for intelligent manufacturing systems to reduce downtime, avoid major hazardous accidents, improve work efficiency, and save costs. The current mainstream health monitoring methods, such as CNN and LSTM, donot consider sequence and time dependencies together. To solve the above problem, an improved residual network and LSTM hybrid model based tool health monitoring is proposed in this paper. First, in the experiment, Wavelet transform was employed as the initial step for time series reconstruction, with the aim of achieving both dimensionality reduction and denoising. The resulting reconstructed time data was fed into the enhanced hybrid model. Then, the improved hybrid model overcomes the shortcomings of the single model, and avoids the mutual interference problem of the conventional combination model in feature extraction. Finally, hybrid model utilizes parallel Deep Residual Networks (DRN) and Long Short- Term Memory (LSTM) networks to extract high-dimensional features from the data. These extracted features are subsequently fed into the fully connected layer via an attention mechanism module to yield the predicted results. The universality and accuracy of the method in the paper were verified through the PHM20 10 dataset.
KW - Improved residual neural network
KW - attention mechanism
KW - long short memory neural network
KW - multivariate time series prediction
KW - tool wear
UR - http://www.scopus.com/inward/record.url?scp=85190974109&partnerID=8YFLogxK
U2 - 10.1109/RICAI60863.2023.10488999
DO - 10.1109/RICAI60863.2023.10488999
M3 - 会议稿件
AN - SCOPUS:85190974109
T3 - 2023 5th International Conference on Robotics, Intelligent Control and Artificial Intelligence, RICAI 2023
SP - 499
EP - 503
BT - 2023 5th International Conference on Robotics, Intelligent Control and Artificial Intelligence, RICAI 2023
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 5th International Conference on Robotics, Intelligent Control and Artificial Intelligence, RICAI 2023
Y2 - 1 December 2023 through 3 December 2023
ER -