A state-of-the-art differential evolution algorithm for parameter estimation of solar photovoltaic models

Photovoltaic (PV) generation systems are vital to the utilization of the sustainable and pollution-free solar energy. However, the parameter estimation of PV systems remains very challenging due to its inherent nonlinear, multi-variable, and multi-modal characteristics. In this paper, we propose a state-of-the-art optimization method, namely, directional permutation differential evolution algorithm (DPDE), to tackle the parameter estimation of several kinds of solar PV models. By fully utilizing the information arisen from the search population and the direction of differential vectors, DPDE can possess a strong global exploration ability of jumping out of the local optima. To verify the performance of DPDE, six groups of experiments based on single, double, triple diode models and PV module models are conducted. Extensive comparative results between DPDE and other fifteen representative algorithms show that DPDE outperforms its peers in terms of the solution accuracy. Additionally, statistical results based on Wilcoxon rank-sum and Friedman tests indicate that DPDE is the most robust and best performing algorithm for the parameter estimation of PV systems.

Automated summary

The DPDE optimization method is proposed for parameter estimation of various solar PV models, which shows better solution accuracy compared to fifteen other algorithms in experiments. Statistical results indicate that DPDE is the most robust and best performing algorithm for parameter estimation of PV systems.