Chandrasekar, A.Ajeya, K.Vinatha Urundady, U.2026-02-042024IEEE Transactions on Industrial Informatics, 2024, 20, 9, pp. 10912-1092115513203https://doi.org/10.1109/TII.2024.3396271https://idr.nitk.ac.in/handle/123456789/21410Accurate prediction of solar irradiance is essential for optimizing renewable energy sources in distributed generation systems due to its significant impact on solar power generation. Despite notable advancements, the inherent variability of irradiance presents challenges for existing models. In this article, we introduce a novel approach for irradiance forecasting using a cascaded combination of regressors applied to transformed process variables. Our method utilizes a gradient-boosted decision tree as the primary regressor to generate initial predictions, which are subsequently refined by a support vector regressor acting as an error correction module. Notably, the secondary regressor's kernel, alongside other hyperparameters, is dynamically learned through reinforcement learning with an RNN-based controller. Evaluation results demonstrate that our prediction-correction framework achieves superior performance compared to state-of-the-art approaches, as indicated by RMSE, MAE, and text{R}^{2} score metrics. Thorough comparative analysis highlights the model's enhanced accuracy and its potential for precise irradiance forecasting. © 2005-2012 IEEE.Decision treesError correctionForecastingHidden Markov modelsReinforcement learningSolar energySolar energy conversionSolar power generationSolar radiationExtreme gradient boostingGradient boostingHidden-Markov modelsKernelPrediction algorithmsPredictive modelsRecurrent neural networkRegression tree analyseRegression treesReinforcement learningsSolar irradiance forecastingSolar irradiancesSupport vector regressionsRecurrent neural networks