The main motivation of this study is to evaluate and compare the efficacy of three computational intelligence
approaches, namely artificial neural network (ANN), genetic programming (GP), and adaptive neuro-fuzzy inference
system (ANFIS) in predicting the energetic performance of a building integrated photovoltaic thermal
(BIPVT) system. This system is capable of cooling PV panels by ventilation/exhaust air in winter/summer and
generating electricity. A performance evaluation criterion (PEC) is defined in this study to examine the overall
performance of the considered BIPVT system. Then, the mentioned methods are used to identify a relationship
between the input and output parameters of the system. The parameter PEC is considered as the essential output
of the system, while the input parameters are the length, width, and depth of the duct underneath the PV panels
and air mass flow rate. To evaluate the accuracy of produced outputs, two statistical indices of R2 and RMSE are
used. As a result, all models presented excellent performance where the ANN model could slightly perform better
performance compared to GP and ANFIS. Finally, the equations belonging to ANN and GP models are derived,
and the GP presents a more suitable formula, due to its simplicity of use, simplicity of concept, and robustness.