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摘要: 針對機器或設備的剩余壽命(Remaining useful life, RUL)預測精度低的問題,提出基于一維卷積神經網絡(Convolutional neural network, CNN)和雙向長短期記憶(Bidirectional long short-term memory, BD-LSTM)的集成神經網絡模型。為了更好地抽取時間序列上的特征,以及產生更多的訓練樣本,采用滑動窗口對數據進行處理,同時采用卡爾曼濾波對數據進行降噪處理,將數據標準化以及設置RUL標簽。與人工提取特征不同,利用一維CNN對數據進行特征提取,并舍棄了CNN中的池化層。然后將提取到的高維特征輸入到BD-LSTM進行回歸預測,并采用Bagging的方式對此神經網絡進行集成來預測RUL。最后通過在NASA的數據集上驗證該模型的有效性,以及相比于其他機器學習或者深度學習模型的優越性,實驗表明所提模型在RUL預測方面更加準確。Abstract: Unexpected failures and unscheduled maintenance activities of mechanical systems might incur considerable waste of resources and high investment costs. Thus, in recent years, prognostics and health management (PHM) has received a lot of attention because of its importance in maintenance cost reduction and machine fault prognostics. The remaining useful life (RUL) of machinery is defined as the length from the current time to the end of its useful life, which is the core technology of PHM. During the operation of machines and equipment, a large amount of data generated by different sensors in the system is collected using various methods. These data often characterize the health status of machinery to a certain extent. By applying the systematic approach to these data, valuable information for strategic decision-making can be obtained. However, traditional machine learning algorithms are usually not efficient enough to handle the complex and nonlinear characteristics of the system and deal with big data. With the rapid development of modern computational hardware and theory, deep learning algorithms show unique advantages in characterizing the system complexity and processing big data. Because of the low-accuracy prediction of the RUL of machines or equipment, a neural network integrating the one-dimensional convolutional neural network (1D CNN) and the bidirectional long short-term memory (BD-LSTM) was proposed. To extract the features of the time series and generate more training samples, the sliding window algorithm was used to process the data and the Kalman filter was applied to denoise the data. Then, the dataset was standardized and the RUL labels were set. Instead of artificial feature extraction, this study used 1D CNN to extract features from the data and discarded the pooling layer of CNN. The extracted high-dimensional features were inputted into the BD-LSTM for regression prediction, and the neural network was integrated by bagging to predict the RUL. Finally, the effectiveness and superiority of the model compared with the machine or deep learning model were verified using the National Aeronautics and Space Administration dataset. Results showed that the proposed model can more accurately predict the RUL than the machine or deep learning model.
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Key words:
- Kalman filter /
- remaining useful life prediction /
- neural network /
- deep learning /
- ensemble learning
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圖 1 一維CNN的操作示意圖
Figure 1. Illustration of the one-dimensional convolutional neural network operation
圖 6 預處理前后的傳感器數據。(a,c)s12傳感器;(b,d) s2傳感器
Figure 6. Sensor data before and after preprocessing: (a,c) Sensor 12; (b,d) Sensor 2
圖 7 卷積層權值分布。(a)第1個卷積層;(b)第2個卷積層;(c)第3個卷積層;(d)第4個卷積層
Figure 7. Convolutional layer weight distribution: (a) the first convolutional layer; (b) the second convolutional layer; (c) the third convolutional layer; (d) the fourth convolutional layer
圖 8 卷積層數目對RMSE的影響
Figure 8. Effect of the number of convolution layers on the root–mean–square error
圖 11 神經元個數對評價指標的影響
Figure 11. Influence of the number of neurons on the evaluation metric
圖 12 時間窗口大小對評價指標的影響
Figure 12. Influence of the time window size on the evaluation metric
圖 13 測試集真實RUL與預測RUL的對比
Figure 13. Comparison of real and predicted RUL in the test set
表 1 基學習器網絡層次表
Table 1. Network hierarchy table of the base learner
Network structure Input shape Output shape Conv1D (30,14) (21,8) Conv1D (21,8) (12,16) Conv1D (12,16) (10,32) BD-LSTM (10,32) (256) Dropout (256) (256) Output (256) (1) 
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