A Novel Piecewise Cubic Hermite Interpolating Polynomial-Enhanced Convolutional Gated Recurrent Method under Multiple Sensor Feature Fusion for Tool Wear Prediction
<p>The framework of PECG method.</p> "> Figure 2
<p>Structure of PECG.</p> "> Figure 3
<p>Real situation of tool wear on machine tools.</p> "> Figure 4
<p>Sensor layout a. PHI Mechatronics Technology Laboratory, Chengdu, China.</p> "> Figure 5
<p>Sensor layout b. PHI Mechatronics Technology Laboratory, Chengdu, China.</p> "> Figure 6
<p>Wear amount collection. PHI Mechatronics Technology Laboratory, Chengdu, China.</p> "> Figure 7
<p>Signal loss and signal drift.</p> "> Figure 8
<p>Monitoring signal data of C4_3.</p> "> Figure 9
<p>Wear stage of C1_1, C2_1, C4_3.</p> "> Figure 10
<p>Interpolation results of C6_1.</p> "> Figure 11
<p>Interpolation results of C8_1.</p> "> Figure 12
<p>Tool wear prediction results of C4_3.</p> "> Figure 13
<p>Tool wear prediction results of C7_9.</p> "> Figure 14
<p>Tool wear performance estimation results of four networks.</p> "> Figure 15
<p>Comparison results with and without interpolation.</p> "> Figure 16
<p>PHM 2010 competition platform [<a href="#B38-sensors-24-01129" class="html-bibr">38</a>].</p> "> Figure 17
<p>Comparison of results on PHM 2010 dataset.</p> "> Figure 18
<p>Tool wear prediction performance of PECG on PHM 2010 dataset.</p> ">
Abstract
:1. Introduction
- By employing the Piecewise Cubic Hermite Interpolating Polynomial method in tandem with an understanding of the patterns associated with missing tool wear data, we successfully interpolated and completed the wear data. This approach effectively resolves the challenge posed by high-dimensional tool wear measurement data collected by sensors, a scenario often characterized by relatively insufficient measurement data.
- We extract local features through the CNN layer, leveraging the feature map as input for the GRU encoder to capture temporal dependencies. The PECG model effectively harnesses the spatial feature learning capacity of CNN while fully optimizing the time series data processing abilities of GRU. This results in the seamless integration and maximization of the strengths of both models, making it particularly well-suited for processing data characterized by both time series and spatial features.
- These two aspects are combined to form a comprehensive PECG method.
2. PCHIP Interpolation Method
- On each subinterval , the polynomial is a cubic Hermite interpolating polynomial for the given data points with specified derivatives at the interpolation points.
- interpolates y, that is, , and the first derivative is continuous. The second derivative is probably not continuous, so jumps at are possible.
- The cubic interpolant is shape-preserving. The slopes at are chosen in such a way that preserves the shape of the data and respects monotonicity. Therefore, on intervals where the data are monotonic, so is , and at points where the data have a local extremum, so does .
3. Model Construction
3.1. Convolutional Neural Network
3.2. Gated Recurrent Unit
3.3. Model Framework
4. Experiment and Result
4.1. Experimental Conditions
4.2. Dataset
Algorithm 1 Signal_Segment (, , ) |
Inputs: —original time-domain signal —width of sliding window —moving step length of sliding window Outputs: —data window matrix |
1: Calculate 2: Initialize 3: for to do 4: if 5: Assign the data from 1 to in to the ith column of the . 6: else if 7: Assign the data who are located from the th to the th in to the ith column of . 8: else 9: Assign the data who are located from the th to the end of to the ith column of and replace the Null in the ith column with 0. 11: End if 12: End for |
4.3. Prediction Results and Comparison
- Pearson Correlation Coefficient (PCC)PCC measures the linear correlation between predicted and actual values, ranging from −1 to 1.
- Mean Absolute Error (MAE)MAE measures the average absolute difference between predicted and actual values.
- Root Mean Squared Error (RMSE)RMSE measures the square root of the average squared difference between predicted and actual values.
- Standard DeviationThe standard deviation of errors is an indicator of the robustness of a model. A lower standard deviation signifies a higher degree of stability of the prediction performance.
- Relative AccuracyRelative accuracy is a measure of the error or difference between a measured or calculated value and the true value of a quantity, ranging from 0 to 1.
4.4. Phm 2010 Dataset Results
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Abbreviations
SAE | Stacked Autoencoder |
RUL | Remaining Useful Life |
GRU | Gated Recurrent Unit |
HMM | Hidden Markov Model |
CNN | Convolutional Neural Network |
CNN Block | Convolutional Neural Network Block |
PCHIP | Piecewise Cubic Hermite Interpolating Polynomial |
PECG | PCHIP-Enhanced ConvGRU |
PCC | Pearson’s Correlation Coefficient |
CNC machine | Computerized Numerical Control Machine |
MGRU | Multi-head gated recurrent unit |
PCA | Principal component analysis |
ANN | Artificial Neural Network |
SVM | Support Vector Machine |
GPR | Gaussian Process Regression |
RNN | Recurrent Neural Network |
DNN | Deep Neural Network |
ReLU | Rectified Linear Unit |
EMA | Exponential Moving Average |
MAE | Mean Absolute Error |
RMSE | Root Mean Square Error |
MAPE | Mean Absolute Percentage Error |
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Layer | Feature Maps | Kernel Size | Parameter Number |
---|---|---|---|
CNN-Block_1 | 128 | 5 | 5504 |
CNN-Block_2-10 | 128 | 5 | 82,304 |
GRU | 384 | 123 | 99,072 |
Condition | Cutter | Spindle Speed | Feed Rate | Depth of Cut |
---|---|---|---|---|
Condition 1 | C1_1 C1_2 | 2750 rpm | 220 mm/min | 1.75 mm |
Condition 2 | C2_1 | 3000 rpm | 200 mm/min | 1.75 mm |
Condition 3 | C3_1 | 3000 rpm | 240 mm/min | 1.75 mm |
Condition 4 | C4_1 …C4_6 | 3000 rpm | 250 mm/min | 1.75 mm |
Condition 5 | C5_1 | 3250 rpm | 275 mm/min | 1.75 mm |
Condition 6 | C6_1 | 3500 rpm | 250 mm/min | 1.75 mm |
Condition 7 | C7_1 …C7_9 | 3500 rpm | 300 mm/min | 1.75 mm |
Condition 8 | C8_1 …C8_7 | 4500 rpm | 400 mm/min | 1.5 mm |
Methods | PCC | MAE | RMSE | MAPE | Standard Deviation |
---|---|---|---|---|---|
pchip [29] | 0.9948 | 3.1701 | 4.7902 | 0.0191 | 4.7682 |
cubic spline | 0.9942 | 3.2968 | 5.0278 | 0.0189 | 5.0265 |
spline | 0.9932 | 3.3427 | 5.4407 | 0.0206 | 5.4278 |
linear | 0.9934 | 3.2514 | 5.4306 | 0.0201 | 5.3822 |
Methods | PCC | Relative Accuracy | MAE | RMSE | Standard Deviation |
---|---|---|---|---|---|
CNN [36] | 0.7957 | 0.7898 | 40.2158 | 56.3456 | 44.3952 |
CNN Blocks | 0.9258 | 0.8097 | 34.0152 | 41.8622 | 28.8696 |
GRU | 0.1947 | 0.6383 | 56.6794 | 70.6391 | 70.6137 |
PECG | 0.9538 | 0.8522 | 23.8362 | 28.5240 | 22.2840 |
Classification | Model/Value | Classification | Value |
---|---|---|---|
Machine model | Roders Tech RFM 760 | Radial cutting depth | 0.125 mm |
Workpiece material | Nickel-based superalloy 718 | Axial cutting depth | 0.2 mm |
Tool | 3-tooth ball nose milling cutter | Number of sensors | 3 |
Spindle speed | 10,400 RPM | Number of sensing channels | 7 |
Feed rate | 1555 mm/min | Sampling frequency | 50 kHZ |
Data | PCC | Relative Accuracy | MAE | RMSE |
---|---|---|---|---|
Original data | 0.9793 | 0.8724 | 18.7152 | 24.8331 |
Missing data | 0.9592 | 0.8344 | 22.4959 | 27.0046 |
Interpolated data | 0.9690 | 0.8622 | 19.6308 | 25.4882 |
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He, J.; Yuan, L.; Lei, H.; Wang, K.; Weng, Y.; Gao, H. A Novel Piecewise Cubic Hermite Interpolating Polynomial-Enhanced Convolutional Gated Recurrent Method under Multiple Sensor Feature Fusion for Tool Wear Prediction. Sensors 2024, 24, 1129. https://doi.org/10.3390/s24041129
He J, Yuan L, Lei H, Wang K, Weng Y, Gao H. A Novel Piecewise Cubic Hermite Interpolating Polynomial-Enhanced Convolutional Gated Recurrent Method under Multiple Sensor Feature Fusion for Tool Wear Prediction. Sensors. 2024; 24(4):1129. https://doi.org/10.3390/s24041129
Chicago/Turabian StyleHe, Jigang, Luyao Yuan, Haotian Lei, Kaixuan Wang, Yang Weng, and Hongli Gao. 2024. "A Novel Piecewise Cubic Hermite Interpolating Polynomial-Enhanced Convolutional Gated Recurrent Method under Multiple Sensor Feature Fusion for Tool Wear Prediction" Sensors 24, no. 4: 1129. https://doi.org/10.3390/s24041129
APA StyleHe, J., Yuan, L., Lei, H., Wang, K., Weng, Y., & Gao, H. (2024). A Novel Piecewise Cubic Hermite Interpolating Polynomial-Enhanced Convolutional Gated Recurrent Method under Multiple Sensor Feature Fusion for Tool Wear Prediction. Sensors, 24(4), 1129. https://doi.org/10.3390/s24041129