Artificial Intelligence-Based Model Predictive Control of a Solar Water Heating System

Solar Water Heating System integrated with AI-MPC

Authors

DOI:

https://doi.org/10.52825/isec.v2i.3388

Keywords:

Solar Water Heating Systems, Model Predictive Control, Artificial Intelligence, Solar Irradiance, Outlet Water Temperature

Abstract

In this study, an artificial intelligence (AI)-assisted model predictive control (MPC) method is developed for enhancing the thermal efficiency of solar water heating systems (SWHS). The efficiency of solar water heating systems depends on solar irradiance, water temperature, and environmental factors, which can be addressed by developing a machine learning (ML)-based predictive MPC method. A predictive method is developed for predicting outlet water temperature based on solar irradiance and water temperature, while an MPC method is developed for improving efficiency. The simulation results have demonstrated that an AI-based MPC method can predict outlet water temperature with high accuracy for a given prediction horizon during changes in solar irradiance, with high agreement between expected and predicted values. The predictive method has an R² value of 0.9844, indicating high accuracy in predicting outlet water temperature.  Thus, this study showed that artificial intelligence model predictive control can improve the efficiency of solar water heating systems. Moreover, the results indicate that the solar water heating system can still accurately predict outlet water temperature despite changes in solar irradiance. Therefore, the efficiency of solar water heating systems can be improved by implementing an artificial intelligence model predictive control.

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Published

2026-06-01

How to Cite

Oboletse, B., Ramotlhagodi, L., & Akano, T. T. (2026). Artificial Intelligence-Based Model Predictive Control of a Solar Water Heating System: Solar Water Heating System integrated with AI-MPC. International Sustainable Energy Conference - Proceedings, 2. https://doi.org/10.52825/isec.v2i.3388

Conference Proceedings Volume

Vol. 2 (2026): ISEC 2026 – 4th International Sustainable Energy Conference

Section

Emerging Energy Technologies and System Integration

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Copyright (c) 2026 Bonang Oboletse, Lawrence Ramotlhagodi, Theddeus Tochukwu Akano

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