Remaining Useful Life Prediction Using Temporal Deep Degradation Network
for Complex Machinery with Attention-based Feature Extraction
- URL: http://arxiv.org/abs/2202.10916v1
- Date: Mon, 21 Feb 2022 10:23:40 GMT
- Title: Remaining Useful Life Prediction Using Temporal Deep Degradation Network
for Complex Machinery with Attention-based Feature Extraction
- Authors: Yuwen Qin, Ningbo Cai, Chen Gao, Yadong Zhang, Yonghong Cheng and Xin
Chen
- Abstract summary: Degradation-related features extracted from the sensor streaming data with neural networks can dramatically improve the accuracy of the RUL prediction.
The Temporal deep degradation network (TDDN) model is proposed to make the RUL prediction with the degradation-related features given by the one-dimensional convolutional neural network (1D CNN)
The results show that the TDDN model can achieve the best RUL prediction accuracy in complex conditions compared to current machine learning models.
- Score: 17.831515307314802
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The precise estimate of remaining useful life (RUL) is vital for the
prognostic analysis and predictive maintenance that can significantly reduce
failure rate and maintenance costs. The degradation-related features extracted
from the sensor streaming data with neural networks can dramatically improve
the accuracy of the RUL prediction. The Temporal deep degradation network
(TDDN) model is proposed to make the RUL prediction with the
degradation-related features given by the one-dimensional convolutional neural
network (1D CNN) feature extraction and attention mechanism. 1D CNN is used to
extract the temporal features from the streaming sensor data. Temporal features
have monotonic degradation trends from the fluctuating raw sensor streaming
data. Attention mechanism can improve the RUL prediction performance by
capturing the fault characteristics and the degradation development with the
attention weights. The performance of the TDDN model is evaluated on the public
C-MAPSS dataset and compared with the existing methods. The results show that
the TDDN model can achieve the best RUL prediction accuracy in complex
conditions compared to current machine learning models. The degradation-related
features extracted from the high-dimension sensor streaming data demonstrate
the clear degradation trajectories and degradation stages that enable TDDN to
predict the turbofan-engine RUL accurately and efficiently.
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