Roy, S, Stevenson, A, Tufail, S et al. (2024). Machine Learning-Driven Reliability Estimation of PV Inverters Considering Alert-Ambient Variability
. IEEE TRANSACTIONS ON INDUSTRY APPLICATIONS, 10.1109/TIA.2024.3522898
Roy, S, Stevenson, A, Tufail, S et al. (2024). Machine Learning-Driven Reliability Estimation of PV Inverters Considering Alert-Ambient Variability
. IEEE TRANSACTIONS ON INDUSTRY APPLICATIONS, 10.1109/TIA.2024.3522898
Weather-induced spatio-temporal degradation limits outdoor PV inverter lifetime and reliability, necessitating advanced data analysis. This study employs a top-down, data-driven approach utilizing multiple machine learning (ML) algorithms to estimate inverter reliability in a 1.4 MW PV power plant, considering factors such as irradiance, humidity, temperature, time of day, and weather conditions. An extensive alert dataset from 17 identical inverters, including alert types, propagation, and frequency, reveals significant correlations with environmental factors and inverter output power, enabling the construction of a performance reliability model. Dual-stage supervised-ML models are evaluated for accuracy, with the 'classification-regression' model by an artificial neural network (ANN) tested on the averaged "Alert-Ambient"dataset, which is outperformed by 'clustering-regression' models using random forest (RF) and K-Nearest Neighbors (KNN) on individual inverter datasets. K-means clustering applies principal component analysis to reduce dimensions, achieving improved accuracy beyond the 80% achieved by ANN on the averaged dataset. Second-stage regression estimates inverter reliability with a mean square error of 0.0195 on the averaged dataset and as low as 0.002 on individual inverter datasets using RF. These findings highlight the method's suitability for estimating PV inverter output reliability under ambient conditions, essential for digital twin development and related applications.
