Table 2.
Overview of review articles on ML and DL applications in photovoltaic (PV) systems (2016–2023)40.
| Authors | Year | Classification | ML models | PV system component | Contribution | Remarks |
|---|---|---|---|---|---|---|
| Youssef et al.41 | 2016 | AI | ANN, FL, ANFIS, GA, GA-fuzzy, NN-fuzzy | PV field | Demonstrates the importance of AI in modeling, sizing, forecasting, and diagnosing faults in PV systems. | Compares the accuracy of different AI techniques with traditional methods, but does not specify the monitoring parameters for each method. |
| Daliento et al.42 | 2016 | Electrical and AI | ANN, SVM, ANFIS, RBN | PV field | Provides a review of various methods used to monitor PV systems. | Well-written and adheres to desired characteristics; no changes were necessary. |
| Mellit et al.43 | 2016 | Electrical and ML | ANN, FL, MSD | PV field | Discusses PV fault information and diagnosis methods. | Primarily focuses on identifying defects. |
| Rodrigues et al.44 | 2017 | M.L. | DT, RF, FL, ANN, GA, Bayesian, KNN, GA-ANN, ANFIS, RVM, k-Means | PV field | Reviews prognosis and diagnosis of defects and covers the number of themes in the study. | Reviews types of studies, faults, input parameters, and PV systems but lacks evaluation of method effectiveness. |
| Madeti et al.45 | 2017 | Conventional and AI | -- | PV field | Reviews detection methods for grid-connected photovoltaic systems. | Already meets desired characteristics; no changes were made. |
| Mellit et al.46 | 2018 | Electrical and ML | ANN, FL, GA, HS | PV field | Comprehensive review on detection methods for grid-connected PV systems. | Focuses on using electrical methods to diagnose faults. |
| Abdulmawjood et al.47 | 2018 | Visual, Thermal, and ML Methods | SVM, k-Means, HMM, BN, ANN, GMM (Gaussian mixture model) | PV field | Covers different types of faults and detection techniques in PV fields. | Discussion is centered on electrical faults, but the detection parameters are not specified for each method. |
| Pillai et al.48 | 2018 | IRT, ML, Others | ANN, LAPART | PV field | Includes a review of almost all PV faults and advanced detection techniques. | Focuses on flaws in detection methods. |
| Ghaffarzadeh et al.49 | 2019 | Electric, ML | ANN, SVM, DT, FL, Kalman filter | PV field | Explains types of defects across a broad spectrum. | Focuses on current faults on the DC and AC sides of the PV system. |
| Appiah50 | 2019 | IRF, ML, DL | ANN, LAPART, KELM, ANFIS | PV field | Reviews types of defects, their origins, and traditional and intelligent detection methods. | Clear and concise, but lacks complexity, precision, and input data. |
| Li et al.51 | 2020 | M.L. | ANN | PV field | Focuses on ANN and hybrid methods applied to defect analysis, including data used, model configuration, and effectiveness. | Compares ANNs with other ML models, showing superiority of ANNs; however, does not compare between ANN models to identify the most efficient one. |
| Venkatesh et al.52 | 2020 | Visual method, IRT, EL, ML | ANN, SVM, NC-NFC, CNN, DT, KNN, FL | PV field | Lists four types of visual defects and detection methods. | Does not take non-visual defects into account; lacks precision. |
| Kurukuru et al.53 | 2021 | ML, DL | ANN, ANFIS, PSO, FL, GA, ABC, CNN, SVM, KNN, LSTM | PV field | Reviews the impact of AI on the PV value chain. | Does not provide precision for each technique. |
| Mansouri et al.54 | 2021 | D.L. | DBN, CNN, RFCN, R-CNN | PV field | Reviews Deep Learning applications in solar cell fault detection. | Examines defects related to cell discoloration, cracking, and delamination in PV systems. |
| Abubakar et al.55 | 2021 | AI, ML | ANN, SVM, LAPART, RBF-ELM, FL, GBSSL, ANFIS, DT | PV field | Discusses characteristics of AI methods, their speed, and effectiveness in detecting defects with minimal errors. | Does not justify inclusion of articles from the last 15 years; does not include accuracy rate for each model. |
| Gaviria et al.56 | 2022 | D.L. | ANN, LSTM, CNN, SVM, RF | PV field | Reviews the interest of ML in PV systems, providing resources for datasets and source codes. | Lacks objectivity and precision in presenting results; includes insignificant articles on defect diagnosis using ML. |
| Hammoudi et al.57 | 2022 | D.L. | CNN, LSTM | PV field | Surveys the interest of Deep Learning and IoT in PV system maintenance. | Limited to discussing deep learning in preventive maintenance on the DC side. |
| Zenebe et al.58 | 2022 | ML, DL | SVM, DA, BN, ANN, KNN, RF, DT, CNN | PV field, Inverter | Reviews ML-based detection methods, showing that ANN and MLP are promising in terms of simplicity and accuracy. | Mainly focuses on defects and detection methods. |
| Yuan et al.59 | 2022 | M.L. | ANN | PV field | Reviews progress of ANN in fault diagnosis. | Lacks information on precision and complexity of each ANN type. |
| Forootan et al.60 | 2022 | ML, DL | SVM, DA, BN, ANN, kNN, RF, DT, CNN, FL, ANFIS, GA, LSTM, RL, MLR, SLR, k-Means, etc. | PV field | Reviews ML and DL algorithms in energy systems. | Fails to consider non-visual defects and lacks precision. |
| Berghout et al.61 | 2022 | ML, DL | SVM, kNN, MLP, LSTM, CNN, Gans | PV field | Discusses monitoring PV systems and defects related to shading and degradation. | Focuses on ML categories, detection techniques, and two types of defects; does not provide accuracy for each model. |
| Puthiyapurayil et al.62 | 2022 | AI, signal-based method | ANN, BPNN, SVM, CNN | Inverter | Lists different methods of diagnosing open-circuit faults in an NPC inverter. | Focuses only on single switch open-circuit faults; rare cases of three switch faults are not covered. |
| Engel et al.63 | 2022 | ML, DL | ANN, CNN, ANFIS, YOLOv4, k-NN, DT, SVM, RF, NB | PV field | Reviews ML advances in prediction, forecasting, sizing, and diagnosis of PV systems. | Compares diagnostic methods, showing better performance of DNN models over non-neural models. |
| Ying-Yi et al.64 | 2022 | Visual and thermal | SVM, kNN, MSD, DT, RF, ANFIS, ANN | PV field | Presents traditional methods of detecting and classifying PV faults and projects AI techniques. | Focuses on traditional methods but demonstrates potential of ML techniques. |
| Osmani et al.65 | 2023 | Conventional methods, AI | SCADA, ANN, KELM (kernel extreme learning machine) | PV field | Critical review of detection methods in the PV field. | Presents DC and AC side faults, focusing on conventional methods and omitting supervised learning methods. |
| Islam et al.66 | 2023 | Artificial intelligence based on ML and DL | AdaBoost, ANN, CNN, RNN, SVM, RF | PV field | Systematic review on identification and diagnosis methods, comparing existing reviews with its own in terms of technical approaches for fault detection. | Identifies most effective DL and ML approaches for PV fault diagnosis, showing DL’s superiority over conventional methods; does not provide accuracy rates for different methods. |