郑州大学计算智能实验室

Computational Intelligence Laboratory

Dr Kunjie Yu has authored a research article in "Applied Energy "


"Multiple learning backtracking search algorithm for estimating parameters of photovoltaic models", An research article written by Computational Intelligence Laboratory's doctor Kunjie  Yu was accepted by Applied Energy(IF=7.182)recently.

The research interests of Dr Kunjie Yu include evolutionary computing, multi-objective optimization, machine learning, modeling and optimization of complex industrial processes, energy optimization, etc. He has authored research articles in peer-reviewed journals including Energy Conversion and Management, Energy, Information Sciences, Knowledge-Based Systems, Computers & Chemical Engineering, Chemometrics and Intelligent Laboratory Systems, Journal of Intelligent Manufacturing.

Introduction:

Obtaining appropriate parameters of photovoltaic models based on measured current-voltage data is crucial for the evaluation, control, and optimization of photovoltaic systems. Although many techniques have been developed to solve this problem, it is still challenging to identify the model parameters accurately and reliably. To improve parameters identification of different photovoltaic models, a multiple learning backtracking search algorithm (MLBSA) is proposed in this paper. In MLBSA, some individuals learn from the current population information and historical population information simultaneously, which aims to maintain population diversity and enhance the exploration ability. While other individuals learn from the best individual of current population to improve the convergence speed and thus enhance the exploitation ability. In addition, an elite strategy based on chaotic local search is developed to further refine the quality of current population. The proposed MLBSA is employed to solve the parameters identification problems of different photovoltaic models, i.e., single diode, double diode, and photovoltaic module. Comprehensive experimental results and analyses demonstrate that MLBSA outperforms other state-of-the-art algorithms in terms of accuracy, reliability, and computational efficiency.