Abstract
The use of intermittent power supplies, such as solar energy, has posed a complex conundrum when it comes to the prediction of the next days’ supply. There have been several approaches developed to predict the power production using Machine Learning methods, such as Artificial Neural Networks (ANNs). In this work, we propose the use of weather variables, such as ambient temperature, solar irradiation, and wind speed, collected from a weather station of a Photovoltaic (PV) system located in Amman, Jordan. The objective is to substitute the aforementioned ambient temperature with the more realistic PV cell temperature with a desire of achieving better prediction results. To this aim, ten physics-based models have been investigated to determine the cell temperature, and those models have been validated using measured PV cell temperatures by computing the Root Mean Square Error (RMSE). Then, the model with the lowest RMSE has been adopted in training a data-driven prediction model. The proposed prediction model is to use an ANN compared to the well-known benchmark model from the literature, i.e., Multiple Linear Regression (MLR). The results obtained, using standard performance metrics, have displayed the importance of considering the cell temperature when predicting the PV power output.
Highlights
Jordan is a nation lying in the heart of the Middle East, surrounded by Palestine, Iraq, Syria, Saudi Arabia, and shares a water border with Egypt
Calculating the cell temperatures The ten physics-based models investigated in this work are used to calculate the cell temperatures of the Applied Science Private University (ASU) solar PV system for the Y~3.5 years (i.e., 16 May 2015 to 31 December 2018) study period
The cell temperatures obtained by the ten models are denoted as Tc1ell to Tc1e0ll
Summary
Jordan is a nation lying in the heart of the Middle East, surrounded by Palestine, Iraq, Syria, Saudi Arabia, and shares a water border with Egypt. Unlike the most of the neighboring nations, Jordan does not have enough crude oil to sustain itself. Jordan relies heavily on the import of the crude oil to satisfy the consumption. This fact meant that Jordan has to import oil at a huge cost which amounts to more than 10% of the total GDP (Department of Statistics 2017; Jaber et al, 2004; Ministry of Energy and Mineral Resources (MEMR) 2017; Ministry of Planning and International Cooperation 2015; National Electric Power Company (NEPCO) 2018). According to national vision and strategy (Ministry of Planning and International Cooperation 2015), it was planned to achieve a contribution of 10% related to the total energy mix in 2020. As a result of the implementation of this strategy, the generation capacity of RE projects carried out on the transmission and distribution grids has been increasing from 1.4 MW in 2014 to 980 MW by late 2018, representing about (18.7%) of the total generation capacity (Figure 1) (Ministry of Planning and International Cooperation, 2015)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
