A Neural Network Classifier with Multi-Valued Neurons for Analog Circuit Fault Diagnosis
Abstract
:1. Introduction
2. The Tools
2.1. Multilayer Neural Network with Multi-Valued Neurons (MLMVN) for Solving Classification and Regression Problems
2.2. SapWin Simulator
3. The Fault Diagnosis Procedure
3.1. Testability Analysis
- Canonic ambiguity group (CAG): an ambiguity group without any other ambiguity group (it is “minimum”);
- Global ambiguity group (GAG): an ambiguity group deriving from the union of two or more canonical ambiguity groups with at least one common element.
3.2. Fault Classes and Fault Classification
- If there is null intersection between CAGs of order 2, then each of them is assumed to be a FC.
- If there is a non-null intersection between the CAGs of order 2, then each GAG given by the intersection of the CAGs of order 2 with non-null intersection is assumed as a FC.
3.3. Fault Parameter Identification
4. Applications
4.1. Sallen-Key Bandpass Filter
- Testability T = 3 (in relative percent 42.85%);
- Number of CAGs = 2 (1 CAG of order 2).
- Multi-parameter: starting from the nominal value, the component parameter is randomly varied in the tolerance range. As specified above, in this example the tolerance values are taken equal to 10% for all the components. A larger tolerance range makes the classification task more challenging.
- In each simulation, just a single component is randomly varied in the range (0.01 pn–100 pn), where pn is the nominal value of the component.
- A set of simulations is generated with no fault element, in order to include also the class “0”, that is the circuit under nominal operating conditions.
- False negative: number of cases in which there was a fault, but the system classified it as a no-fault case.
- False positive: number of cases in which there was no fault, but the classifier returned a fault in the circuit.
- Precision: the percent of cases that were actually faulty, among all the cases that actually were detected to be faulty.
- Fault diagnosability: the percent of cases which were correctly detected to have a fault, among all the fault cases.
- Accuracy: ratio of correctly classified test cases to all the test cases.
- The number of neurons is varied from to (typically 10–300, but it can be increased if the result is not clear, that is if there is not a maximum in the range), using an incremental step 10.
- The number of hidden layer neurons is refined in a neighborhood of the best number obtained at point 1 and ±20, using a step 2 at this time.
4.2. Lowpass Biquadratic Filter
- Testability T = 5 (in relative percent 38.46%)
- Number of CAGs = 55 (among these, 7 CAGs have order 2)
- GAG1 = (R6, R7, R8, C2)
- GAG2 = (R9, R11)
4.3. A Network Filter
- R3rd = 0.2 Ω; C3rd = 100 μF; L3rd = 11.258 mH;
- R5th = 0.5 Ω; C5th = 100 μF; L5th = 4.053 mH;
- R7th = 0.1 Ω; C7th = 5 mF; L7th = 10 mH.
- For each simulation, 7 frequencies are chosen, wherein magnitude and phase are measured; in this case, the used frequencies are those of 1st, 3rd, 5th, and 7th harmonics (in the range 50–350 Hz), increased by interposed samples.
- In this case, the tolerances are chosen following the typical specifications for this kind of filter, which is equal to 2% for capacitors and inductors and 5% for resistances.
- In each simulation, a single component value is randomly variated in the range (0.01 pn–100 pn), where pn is the nominal value of the component.
- The total number of simulations is 4000; 2500 are used for training and 1500 for failure classification.
- There was a low sensitivity of some parameters of the system and then a small variation in the space of the solutions. In Figure 5, for instance, the parametric magnitude sensitivities of L7th is shown, which were associated to the FCs with the worst result.
5. Conclusions
Supplementary Materials
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Training Set | Test Set | |||
MLMVN | SVM | MLMVN | SVM | |
False negative | (23/700) 3.29% | (24/700) 3.43% | (11/300) 3.67% | (12/300) 4.00% |
False positive | (0/700) 0.00% | (3/700) 0.43% | (0/300) 0.00% | (3/300) 1.00% |
Precision | 100.00% | 99.33% | 100.00% | 98.29% |
Fault diagnosability | 95.20% | 94.87% | 94.52% | 93.48% |
Accuracy % | ||||
MLMVN | SVM | MLMVN | SVM | |
Overall | 92.86 | 93.86 | 91.67 | 90.00 |
0 (healthy) | 100.00 | 98.71 | 100.00 | 97.41 |
1 (C1) | 87.38 | 71.05 | 92.11 | 68.75 |
2 (C2) | 96.51 | 98.65 | 90.91 | 97.30 |
3 (R1) | 87.88 | 98.77 | 89.29 | 87.10 |
4 (R2) | 96.00 | 95.52 | 89.66 | 86.67 |
5 (R3) | 74.29 | 92.94 | 70.59 | 81.82 |
6 (GAG) | 93.67 | 91.76 | 92.31 | 88.89 |
FC | Nominal Value | FCerr% (MLMVNN) |
---|---|---|
1 (C1) | 5 × 10−9 F | 17.12 |
2 (C2) | 5 × 10−9 F | 11.4 |
3 (R1) | 5.18 kΩ | 26.2 |
4 (R2) | 1000 Ω | 14.9 |
5 (R3) | 2 kΩ | 17.7 |
6 (GAG) | 4 kΩ (R4–R5) | 31.2 |
Training Set | Test Set | |||
MLMVN | SVM | MLMVN | SVM | |
False negative | (16/1500) 1.07% | (13/1500) 0.87% | (3/500) 0.60% | (8/500) 1.60% |
False positive | (7/1500) 0.47% | (1/1500) 0.07% | (1/500) 0.20% | (1/500) 0.20% |
Precision | 99.21% | 99.89% | 99.66% | 99.66% |
Fault diagnosability | 98.26% | 98.61% | 99.01% | 97.38% |
Accuracy % | ||||
MLMVN | SVM | MLMVN | SVM | |
Overall | 98.40 | 98.93 | 98.80 | 95.60 |
0 (healthy) | 98.79 | 99.82 | 99.49 | 99.49 |
1 (C1) | 100.00 | 100.00 | 100.00 | 100.00 |
2 (GAG1) | 100.00 | 100.00 | 100.00 | 97.37 |
3 (R1) | 100.00 | 100.00 | 100.00 | 96.30 |
4 (R10) | 100.00 | 91.95 | 97.56 | 84.62 |
5 (GAG2) | 88.28 | 92.47 | 84.21 | 76.47 |
6 (R2) | 100.00 | 100.00 | 100.00 | 100.00 |
7 (R3) | 97.96 | 99.12 | 96.77 | 91.89 |
8 (R4) | 100.00 | 100.00 | 100.00 | 97.14 |
9 (R5) | 100.00 | 100.00 | 100.00 | 97.30 |
FC | Nominal Value | FCerr% (MLMVNN) |
---|---|---|
1 (C1) | 1 × 10−7 F | 8.2 |
2 (GAG1) | 1 × 10−7 F (C2) | 9.6 |
3 (R1) | 1000 Ω | 62.6 |
4 (R10) | 1000 Ω | 51.0 |
5 (GAG2) | 1000 Ω (R11) | 47.1 |
6 (R2) | 1000 Ω | 2.3 |
7 (R3) | 1000 Ω | 38.5 |
8 (R4) | 500 Ω | 2.8 |
9 (R5) | 1000 Ω | 46.2 |
Training Set | Test Set | |||
MLMVN | SVM | MLMVN | SVM | |
False negative | (131/2500) 5.24% | (185/2500) 7.40% | (98/1500) 6.53% | (120/1500) 8.00% |
False positive | (0/2500) 0.00% | (0/2500) 0.00% | (0/1500) 0.00% | (0/1500) 0.00% |
Precision | 100.00% | 100.00% | 100.00% | 100.00% |
Fault diagnosability | 92.02% | 88.73% | 89.55% | 87.21% |
Accuracy | ||||
MLMVN | SVM | MLMVN | SVM | |
Overall | 93.68 | 88.28 | 89.80 | 87.33 |
0 (healthy) | 100.00 | 100.00 | 100.00 | 100.00 |
1 (C3rd) | 98.40 | 98.40 | 94.69 | 98.23 |
2 (C5th) | 96.81 | 79.79 | 93.58 | 77.06 |
3 (C7th) | 100.00 | 100.00 | 87.76 | 100.00 |
4 (L3rd) | 90.51 | 87.34 | 84.00 | 78.00 |
5 (L5th) | 98.56 | 86.54 | 94.90 | 85.71 |
6 (L7th) | 44.28 | 40.80 | 29.41 | 28.43 |
7 (R3rd) | 91.12 | 55.03 | 85.42 | 56.25 |
8 (R5th) | 97.75 | 94.94 | 84.76 | 88.57 |
9 (R7th) | 100.00 | 100.00 | 95.73 | 100.00 |
Training Set | Test Set | |||
MLMVN | SVM | MLMVN | SVM | |
False negative | (1/2500) 0.04% | (0/2500) 0.00% | (2/824) 0.24% | (3/824) 0.36% |
False positive | (0/2500) 0.00% | (0/2500) 0.00% | (0/824) 0.00% | (0/824) 0.00% |
Precision | 100.00% | 100.00% | 100.00% | 100.00% |
Fault diagnosability | 99.94% | 100.00% | 99.63% | 99.44% |
Accuracy | ||||
MLMVN | SVM | MLMVN | SVM | |
Overall | 99.04 | 95.88 | 97.09 | 95.39 |
0 (healthy) | 100.00 | 100.00 | 100.00 | 100.00 |
1 (C3rd) | 97.55 | 94.12 | 95.08 | 93.44 |
2 (C5th) | 100.00 | 84.51 | 98.48 | 89.39 |
3 (C7th) | 100.00 | 100.00 | 98.88 | 100.0 |
4 (L3rd) | 91.89 | 91.89 | 87.50 | 86.11 |
5 (L5th) | 100.00 | 84.62 | 100.00 | 84.85 |
6 (L7th) | 97.73 | 100.00 | 87.50 | 100.00 |
7 (R3rd) | 100.00 | 100.00 | 98.25 | 98.25 |
8 (R5th) | 100.00 | 100.00 | 90.70 | 88.37 |
9 (R7th) | 100.00 | 100.00 | 95.38 | 98.46 |
FC | Nominal Value | Mean Error % (MLMVNN) |
---|---|---|
1 (C3rd) | 1 × 10−4 F | 7.9 |
2 (C5th) | 1 × 10−4 F | 25.1 |
3 (C7th) | 5 × 10−4 F | 7.7 |
4 (L3rd) | 11.258 mH | 48.1 |
5 (L5th) | 4.053 mH | 15.5 |
6 (L7th) | 10 mH | 36.2 |
7 (R3rd) | 0.2 Ω | 33.7 |
8 (R5th) | 0.5 Ω | 12.1 |
9 (R7th) | 0.1 Ω | 3.1 |
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Aizenberg, I.; Belardi, R.; Bindi, M.; Grasso, F.; Manetti, S.; Luchetta, A.; Piccirilli, M.C. A Neural Network Classifier with Multi-Valued Neurons for Analog Circuit Fault Diagnosis. Electronics 2021, 10, 349. https://doi.org/10.3390/electronics10030349
Aizenberg I, Belardi R, Bindi M, Grasso F, Manetti S, Luchetta A, Piccirilli MC. A Neural Network Classifier with Multi-Valued Neurons for Analog Circuit Fault Diagnosis. Electronics. 2021; 10(3):349. https://doi.org/10.3390/electronics10030349
Chicago/Turabian StyleAizenberg, Igor, Riccardo Belardi, Marco Bindi, Francesco Grasso, Stefano Manetti, Antonio Luchetta, and Maria Cristina Piccirilli. 2021. "A Neural Network Classifier with Multi-Valued Neurons for Analog Circuit Fault Diagnosis" Electronics 10, no. 3: 349. https://doi.org/10.3390/electronics10030349
APA StyleAizenberg, I., Belardi, R., Bindi, M., Grasso, F., Manetti, S., Luchetta, A., & Piccirilli, M. C. (2021). A Neural Network Classifier with Multi-Valued Neurons for Analog Circuit Fault Diagnosis. Electronics, 10(3), 349. https://doi.org/10.3390/electronics10030349