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Satellite based fault diagnosis of photovoltaic systems using recurrent neural networks

Jonas Van Gompel (UGent) , Domenico Spina (UGent) and Chris Develder (UGent)
(2022) APPLIED ENERGY. 305.
Author
Organization
Abstract
Due to manufacturing defects and wear, faults in photovoltaic (PV) systems are often unavoidable. The effects range from energy losses to risk of fire and electrical shock, making early fault detection and identification crucial. Literature focuses on PV fault diagnosis using dedicated on-site sensors or high-frequency current and voltage measurements. Although these existing techniques are accurate, they are not economical for widespread adoption, leaving many PV systems unmonitored. In contrast, we introduce a machine learning based technique that relies on satellite weather data and low-frequency inverter measurements for accurate fault diagnosis of PV systems. This allows one to adopt machine learning based fault diagnosis even for PV systems without on-site sensors. The proposed approach relies on a recurrent neural network to identify six relevant types of faults, based on the past 24 h of measurements, as opposed to only taking into account the most recent measurement. Additionally, whereas state-of-the-art methods are limited to identifying the fault type, our model also estimates the output power reduction stemming from the fault, i.e., the fault severity. Comprehensive experiments on a simulated PV system demonstrate that this approach is sensitive to faults with a severity as small as 5%, reaching an accuracy of 96.9% +/- 1.3% using exact weather data and 86.4% +/- 2.1% using satellite weather data. Finally, we show that the model generalizes well to climates other than the climate of its training data and that the model is also able to detect unknown faults, i.e., faults that were not represented in the training data.
Keywords
VOLTAGE, FOREST, Photovoltaics, Recurrent neural network, Time series classification, Fault diagnosis, Fault detection

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Citation

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MLA
Van Gompel, Jonas, et al. “Satellite Based Fault Diagnosis of Photovoltaic Systems Using Recurrent Neural Networks.” APPLIED ENERGY, vol. 305, 2022, doi:10.1016/j.apenergy.2021.117874.
APA
Van Gompel, J., Spina, D., & Develder, C. (2022). Satellite based fault diagnosis of photovoltaic systems using recurrent neural networks. APPLIED ENERGY, 305. https://doi.org/10.1016/j.apenergy.2021.117874
Chicago author-date
Van Gompel, Jonas, Domenico Spina, and Chris Develder. 2022. “Satellite Based Fault Diagnosis of Photovoltaic Systems Using Recurrent Neural Networks.” APPLIED ENERGY 305. https://doi.org/10.1016/j.apenergy.2021.117874.
Chicago author-date (all authors)
Van Gompel, Jonas, Domenico Spina, and Chris Develder. 2022. “Satellite Based Fault Diagnosis of Photovoltaic Systems Using Recurrent Neural Networks.” APPLIED ENERGY 305. doi:10.1016/j.apenergy.2021.117874.
Vancouver
1.
Van Gompel J, Spina D, Develder C. Satellite based fault diagnosis of photovoltaic systems using recurrent neural networks. APPLIED ENERGY. 2022;305.
IEEE
[1]
J. Van Gompel, D. Spina, and C. Develder, “Satellite based fault diagnosis of photovoltaic systems using recurrent neural networks,” APPLIED ENERGY, vol. 305, 2022.
@article{8723447,
  abstract     = {{Due to manufacturing defects and wear, faults in photovoltaic (PV) systems are often unavoidable. The effects range from energy losses to risk of fire and electrical shock, making early fault detection and identification crucial. Literature focuses on PV fault diagnosis using dedicated on-site sensors or high-frequency current and voltage measurements. Although these existing techniques are accurate, they are not economical for widespread adoption, leaving many PV systems unmonitored. In contrast, we introduce a machine learning based technique that relies on satellite weather data and low-frequency inverter measurements for accurate fault diagnosis of PV systems. This allows one to adopt machine learning based fault diagnosis even for PV systems without on-site sensors. The proposed approach relies on a recurrent neural network to identify six relevant types of faults, based on the past 24 h of measurements, as opposed to only taking into account the most recent measurement. Additionally, whereas state-of-the-art methods are limited to identifying the fault type, our model also estimates the output power reduction stemming from the fault, i.e., the fault severity. Comprehensive experiments on a simulated PV system demonstrate that this approach is sensitive to faults with a severity as small as 5%, reaching an accuracy of 96.9% +/- 1.3% using exact weather data and 86.4% +/- 2.1% using satellite weather data. Finally, we show that the model generalizes well to climates other than the climate of its training data and that the model is also able to detect unknown faults, i.e., faults that were not represented in the training data.}},
  articleno    = {{117874}},
  author       = {{Van Gompel, Jonas and Spina, Domenico and Develder, Chris}},
  issn         = {{0306-2619}},
  journal      = {{APPLIED ENERGY}},
  keywords     = {{VOLTAGE,FOREST,Photovoltaics,Recurrent neural network,Time series classification,Fault diagnosis,Fault detection}},
  language     = {{eng}},
  pages        = {{9}},
  title        = {{Satellite based fault diagnosis of photovoltaic systems using recurrent neural networks}},
  url          = {{http://doi.org/10.1016/j.apenergy.2021.117874}},
  volume       = {{305}},
  year         = {{2022}},
}
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