Edge Computing and Fault Diagnosis of Rotating Machinery Based on MobileNet in Wireless Sensor Networks for Mechanical Vibration
Abstract
:1. Introduction
- (1)
- The operational status of rotating machinery is acquired noninvasively, eliminating the need for intricate wired cable installations and averting any damage to the monitoring equipment.
- (2)
- Inspired by the small and lightweight DL model for mechanical equipment monitoring, a lightweight compressed MobileNet for MvWSNs senor node is proposed.
- (3)
- The proposed method was tested on a sensor node to demonstrate its efficiency on a source-constrained embedded platform, including model size, time efficiency, and accuracy.
2. Related Work
2.1. Lightweight Deep Learning Model
2.2. MobileNet
3. Proposed Method
3.1. Proposed Lightweight Model
- Step 1: Vibration signal acquisition. The MvWSNs node is deployed in the drivetrain diagnostic simulator (DDS) to collect the vibration signals of the X and Y axes of the input and output axes.
- Step 2: Model training and dataset partitioning. The collected vibration data is divided into multiple samples with a sample length of 1024. Then, the samples are divided into training set data and testing set data. The training set data is annotated with five samples: normal (N), gear pitting (F1), root crack (F2), bearing outer ring fault (F3), and inner ring fault (F4). Note that the test set data is not labeled with samples.
- Step 3: Model construction and offline training. The limited computing resources of the MvWSNs node is unable to support model training. Therefore, the model training is still being conducted on a high-performance computer.
- Step 4: Online testing of model accuracy. Unknown test set data is inputted into the lightweight model trained in the previous step for fault diagnosis and classification, and the accuracy of diagnostic testing is calculated.
- Step 5: Model deployment. The model is deployed to MvWSNs nodes for online monitoring and fault diagnosis.
3.2. Model Deployment in MvWSNs
4. Experiments and Analysis
4.1. Performance on Open Data
4.2. Fault Simulator Dataset of DDS
4.3. Model Training
4.4. Testing Results
4.5. Comparison Result on Mechanical WSN
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Layer | Input Shape |
---|---|
Convolution/2 | (32, 32, 1) |
Depth-wise convolution/1 | (16, 16, 8) |
Point-wise convolution/1 | (16, 16, 16) |
Depth-wise convolution/2 | (8, 8, 16) |
Point-wise convolution/2 | (8, 8, 32) |
Depth-wise convolution/1 | (8, 8, 32) |
Point-wise convolution/1 | (8, 8, 64) |
Depth-wise convolution/2 | (4, 4, 64) |
Point-wise convolution/2 | (4, 4, 128) |
Average pooling/1 | (1, 1, 128) |
Fully connected | (1, 1, 128) |
Softmax | (1, 1, 5) |
Parameter | Size |
---|---|
Size of input data | 1024 (4 kB) |
Size of output data | 5 (20 B) |
Complexity | 424,944 times |
Size of weight | 52,180 B |
Size of activation function | 20,994 B |
Requirement of Flash memory | 50.94 kB |
Requirement of RAM memory | 24.52 kB |
Gearbox Category | Level | Gear Category | Number of Teeth | Number of Gears | Gear Ratio |
---|---|---|---|---|---|
Planetary gearbox | 1st | Sun gear | 20 | 1 | 6 |
Inner gear ring | 100 | 1 | |||
Planetary gear | 40 | 3 | |||
2nd | Sun gear | 28 | 1 | 4.57 | |
Inner gear ring | 100 | 1 | |||
Planetary gear | 36 | 3 | |||
Fixed shaft gearbox | 1st | Driving gear | 100 | 1 | 0.29 |
Drive gear | 29 | 1 | |||
2nd | Driving gear | 36 | 1 | 2.5 | |
Drive gear | 90 | 1 |
Class Label | Health States Description |
---|---|
0 | Normal |
1 | Tooth surface pitting fault of gear |
2 | Tooth root crack fault of gear |
3 | Outer fault of bearing |
4 | Inner fault of bearing |
Condition | Accuracy |
---|---|
N | 99.9% |
F1 | 99.3% |
F2 | 99% |
F3 | 98.4% |
F4 | 98.9% |
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Share and Cite
Huang, Y.; Liang, S.; Cui, T.; Mu, X.; Luo, T.; Wang, S.; Wu, G. Edge Computing and Fault Diagnosis of Rotating Machinery Based on MobileNet in Wireless Sensor Networks for Mechanical Vibration. Sensors 2024, 24, 5156. https://doi.org/10.3390/s24165156
Huang Y, Liang S, Cui T, Mu X, Luo T, Wang S, Wu G. Edge Computing and Fault Diagnosis of Rotating Machinery Based on MobileNet in Wireless Sensor Networks for Mechanical Vibration. Sensors. 2024; 24(16):5156. https://doi.org/10.3390/s24165156
Chicago/Turabian StyleHuang, Yi, Shuang Liang, Tingqiong Cui, Xiaojing Mu, Tianhong Luo, Shengxue Wang, and Guangyong Wu. 2024. "Edge Computing and Fault Diagnosis of Rotating Machinery Based on MobileNet in Wireless Sensor Networks for Mechanical Vibration" Sensors 24, no. 16: 5156. https://doi.org/10.3390/s24165156
APA StyleHuang, Y., Liang, S., Cui, T., Mu, X., Luo, T., Wang, S., & Wu, G. (2024). Edge Computing and Fault Diagnosis of Rotating Machinery Based on MobileNet in Wireless Sensor Networks for Mechanical Vibration. Sensors, 24(16), 5156. https://doi.org/10.3390/s24165156