Health Monitoring and Fault Detection in Photovoltaic Systems in Central Greece Using Artificial Neural Networks

Ρουμπακιάς, Ηλίας; Stamatelos, A. M.

doi:10.3390/app122312016

Cited by 5 publications

(4 citation statements)

References 35 publications

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“…Days with reported faults are rejected from Figure 22 in order to decouple the effect of degradation. The error in these faulty conditions was over 30% for faults in a string, whereas a faulty panel was associated with a deviation of 10-20% and faults of near shading of 6-10% compared to 5% during normal operation [58]. Most of the PV panels' manufacturers declare a linear degradation of the semiconductor, which is included in the warranty conditions.…”

Section: Neural Network Simulationmentioning

confidence: 99%

Comparative Performance Analysis of a Grid-Connected Photovoltaic Plant in Central Greece after Several Years of Operation Using Neural Networks

Ρουμπακιάς

Stamatelos

2023

Sustainability

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The increasing installed volume of grid-connected PV systems in modern electricity networks induces variability and uncertainty factors which must be addressed from several different viewpoints, including systems’ protection and management. This study aims to estimate the actual performance and degradation of photovoltaic (PV) parks in Central Greece after several years of operation. Monitoring data over several years are analyzed and filtered, the performance ratio and normalized efficiency are computed, and five different ANNs are employed: (i) a feed-forward network (one hidden layer); (ii) a deep feed-forward network (two hidden layers); (iii) a recurrent neural network; (iv) a cascade-forward network; and (v) a nonlinear autoregressive network. The following inputs are employed: in-plane irradiance; backsheet panel temperature; airmass; clearness index; and DC voltage of the inverter. Monitoring data from an 8-year operation of a grid-connected PV system are employed for training, testing, and validation of these networks. They act as a baseline, built from the first year, and the computed metrics act as indicators of faults or degradation. Best accuracy is reached with the DFFNN. The ANNs are trained with data from the first year of operation, and output prediction is carried out for the remaining years. Annual electricity generation exceeds 1600 kWh /kWp, and MAPE values show an increasing trend over the years. This fact indicates a possible change in PV performance.

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Section: Neural Network Simulationmentioning

confidence: 99%

Comparative Performance Analysis of a Grid-Connected Photovoltaic Plant in Central Greece after Several Years of Operation Using Neural Networks

Ρουμπακιάς

Stamatelos

2023

Sustainability

Self Cite

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“…The realization of accurate identification of different discharge signals of cable terminals is helpful to obtain accurate partial discharge signals of cable terminals and to diagnose the process of internal fault occurrence in cable terminals [32][33][34]. With rapid developments in artificial intelligence (AI), its techniques are now widely used in electrical and energy systems [35][36][37][38][39][40][41][42][43][44][45][46]. These AI-related techniques include not only advanced methods but also foundational data analysis methods, which are integral to developing AI-powered pattern recognition methods.…”

Section: Introductionmentioning

confidence: 99%

Accurate Identification of Partial Discharge Signals in Cable Terminations of High-Speed Electric Multiple Unit Using Wavelet Transform and Deep Belief Network

Liu,

Li,

Zhang

et al. 2024

Applied Sciences

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Cable termination serves as a crucial carrier for high-speed train power transmission and a weak part of the cable insulation system. Partial discharge detection plays a significant role in evaluating insulation status. However, field testing signals are often contaminated by external corona interference, which affects detection accuracy. This paper proposes a classification model based on wavelet transform (WT) and deep belief network (DBN) to accurately and rapidly identify corona discharge in the partial discharge signals of vehicle-mounted cable terminals. The method utilizes wavelet transform for noise reduction, employing the sigmoid activation function and analyzing the impact of WT on DBN classification performance. Research indicates that this method can achieve an accuracy of over 89% even with limited training samples. Finally, the reliability of the proposed classification model is verified using measured mixed signals.

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“…Second, the threshold methods estimate the power generation of PV systems, and compare the estimations with actually measured power generation. By analyzing the differences, users detect different abnormalities, such as shading effects [27], snow accumulation [28], maximum power point tracking error [29], and faulty conditions of DC-AC converters [15,30,31]. The threshold methods have the advantage of working well even without fault-labeled data.…”

Section: Introductionmentioning

confidence: 99%

“…The threshold methods have the advantage of working well even without fault-labeled data. However, the thresholds are typically predetermined [31], or determined by monitoring data profiles [30], which has room for improvement.…”

Section: Introductionmentioning

confidence: 99%

Label-Free Fault Detection Scheme for Inverters of PV Systems: Deep Reinforcement Learning-Based Dynamic Threshold

et al. 2023

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Generally, photovoltaic (PV) fault detection approaches can be divided into two groups: end-to-end and threshold methods. The end-to-end method typically uses a deep neural network (DNN) to learn fault patterns from labeled datasets, which directly detect whether faults occur or not. The threshold method first estimates power generation and uses thresholds to detect atypical deviations of measured values from estimated ones. The former method heavily relies on fault-labeled data and, therefore, requires the collection of abnormal event records, which is usually difficult, due to the sparseness of these events. The latter method typically uses statistical approaches, such as 3-sigma, to find thresholds, and it can be practically utilized without fault labels. However, setting a threshold with a proper confidence interval is still challenging, as PV power generation is sensitive to variations in environmental conditions, such as irradiance, ambient temperature, wind speed and humidity. In this paper, we propose a novel deep reinforcement learning (DRL)-based label-free fault detection scheme in which thresholds are dynamically assigned with suitable confidence intervals under varying environmental conditions. Various weather properties were used as input features (i.e., states) to a DRL agent, and proper thresholds were estimated in real time from the actions of the DRL agent. To this end, a reward function was designed for learning proper thresholds without fault labels under different weather conditions. To evaluate the performance of the proposed scheme, the PV dataset of the National Institute of Standards and Technology (NIST) was used, as it includes paired records of local weather and PV generations. The DRL-based scheme was compared with static and conventional dynamic threshold methods, based on statistical approaches. The results revealed that the proposed scheme outperformed the existing methods, providing a 5.67% higher F1-score in the NIST dataset.

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Health Monitoring and Fault Detection in Photovoltaic Systems in Central Greece Using Artificial Neural Networks

Cited by 5 publications

References 35 publications

Comparative Performance Analysis of a Grid-Connected Photovoltaic Plant in Central Greece after Several Years of Operation Using Neural Networks

Comparative Performance Analysis of a Grid-Connected Photovoltaic Plant in Central Greece after Several Years of Operation Using Neural Networks

Accurate Identification of Partial Discharge Signals in Cable Terminations of High-Speed Electric Multiple Unit Using Wavelet Transform and Deep Belief Network

Label-Free Fault Detection Scheme for Inverters of PV Systems: Deep Reinforcement Learning-Based Dynamic Threshold

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