Fault Diagnosis Method for Engine Control System Based on Probabilistic Neural Network and Support Vector Machine
Abstract
:1. Introduction
2. Fault Diagnosis Algorithm Selection
2.1. Introduction of Probabilistic Neural Network
2.2. Introduction of Support Vector Machines
- Linear kernel function: .
- Polynomial kernel function: .
- Radial basis kernel function: .
- Two-layer perceptron kernel function: .
3. Analysis of the Fault State and Establishment of the Fault Data Sample
3.1. Analysis of Fault Signal
3.1.1. Fuel Injection Failure of the Injector
3.1.2. Low Fuel Supply Pressure
3.1.3. Leaks of the Exhaust Pipe
3.1.4. The Intermittently Flameout of Engine
3.2. Creation of the Fault Diagnosis Data Sample
3.3. Data Processing
4. Introduction to Particle Swarm Optimization Algorithm
5. Results and Analysis of the Optimization Algorithm
5.1. Results of the Probabilistic Neural Optimization
5.2. Results of the Support Vector Machine Optimization
5.3. Comparison and Analysis of Diagnostic Method Results
6. Conclusions
Author Contributions
Funding
Conflicts of Interest
References
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Fault Type | The Signature Signals Required for Establishing the Mapping |
---|---|
The fuel injection failure of the injector | Throttle opening, air-fuel ratio signal and vibration peak |
Low fuel supply pressure | Rotating speed signal, vibration peak, air-fuel ratio signal, throttle opening, torque signal and cylinder temperature signal |
Leaks of the exhaust pipe | Air-fuel ratio signal |
The intermittent flameout of engine | Air-fuel ratio signal, rotating speed signal and vibration frequency domain signal |
Rotating Speed (r/min) | Throttle Opening (%) | Vibration Frequency (Hz) | Vibration Peak Value (V) | Cylinder Temperature of Number 1 (°C) | Cylinder Temperature of Number 2 (°C) | Number One Cylinder λ | Number Two-Cylinder λ | State |
---|---|---|---|---|---|---|---|---|
3539 | 16.563 | 59 | 2.30 | 158 | 159 | 0.98 | 1.02 | 1 |
3508 | 14.813 | 59 | 2.82 | 159 | 158 | 0.91 | 0.93 | 2 |
3494 | 17.813 | 58 | 1.95 | 138 | 151 | 1.13 | 1.26 | 3 |
3575 | 16.813 | 58 | 2.28 | 157 | 159 | 1.31 | 1.03 | 4 |
3461 | 16.875 | 59 | 2.23 | 158 | 157 | 1.20 | 1.23 | 5 |
Kernel Function | Accuracy | SVM Train Parameter Options |
---|---|---|
Linear kernel function | 96.4% | c = 2, g = 1, t = 0 |
Polynomial kernel function | 98.4% | c = 2, g = 1, t = 1 |
Radial basis kernel function | 93.6% | c = 2, g = 1, t = 2 |
Sigmoid kernel function | 40.4% | c = 2, g = 1, t = 3 |
Classification Model | Classification Accuracy (%) | Optimized Accuracy with PSO (%) |
---|---|---|
Probabilistic neural network | 92.8 | 96.4 |
C/v-SVM linear kernel function | 96.4/96.4 | 97.6/98.4 |
C/v-SVM polynomial kernel function | 98.4/84.4 | 98.4/98.8 |
C/v-SVM radial basis kernel function | 93.6/99.2 | 99.2/96.8 |
C/v-SVM Sigmoid kernel function | 40.4/87.6 | 98.8/92.4 |
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Wang, B.; Ke, H.; Ma, X.; Yu, B. Fault Diagnosis Method for Engine Control System Based on Probabilistic Neural Network and Support Vector Machine. Appl. Sci. 2019, 9, 4122. https://doi.org/10.3390/app9194122
Wang B, Ke H, Ma X, Yu B. Fault Diagnosis Method for Engine Control System Based on Probabilistic Neural Network and Support Vector Machine. Applied Sciences. 2019; 9(19):4122. https://doi.org/10.3390/app9194122
Chicago/Turabian StyleWang, Bo, Hongwei Ke, Xiaodong Ma, and Bing Yu. 2019. "Fault Diagnosis Method for Engine Control System Based on Probabilistic Neural Network and Support Vector Machine" Applied Sciences 9, no. 19: 4122. https://doi.org/10.3390/app9194122
APA StyleWang, B., Ke, H., Ma, X., & Yu, B. (2019). Fault Diagnosis Method for Engine Control System Based on Probabilistic Neural Network and Support Vector Machine. Applied Sciences, 9(19), 4122. https://doi.org/10.3390/app9194122