Boosting slime mould algorithm for parameter identification of photovoltaic models

• Published in: Energy (Oxford) Vol. 234; p. 121164
• Main Authors: Liu, Yun, Heidari, Ali Asghar, Ye, Xiaojia, Liang, Guoxi, Chen, Huiling, He, Caitou
• Format: Journal Article
• Language: English
• Published: Oxford Elsevier Ltd 01.11.2021; Elsevier BV
• Subjects: Algorithms; Chaos theory; diodes; electricity; energy; France; High temperature; Irradiance; light intensity; Mathematical models; Optimization; Parameter estimation; Parameter identification; Photovoltaic cells; Photovoltaics; Random numbers; Slime; Slime molds; Slime mould algorithm; Solar cells; solar collectors; Solar energy; Solar energy conversion; Stability; Swarm-intelligence; France; Swarm-intelligence; Parameter estimation; Slime mould algorithm; Optimization
• ISSN: 0360-5442; 1873-6785
• DOI: 10.1016/j.energy.2021.121164

Estimating the photovoltaic model's unknown parameters efficiently and accurately can determine the solar cell's efficacy in converting the solar energy into electricity. For this purpose, this work proposes an advanced slime mould algorithm (SMA) integrated Nelder-Mead simplex strategy and chaotic map, called CNMSMA. Chaotic maps replace the random number rand that affects the choice of location updating strategy to improve the exploratory patterns. Also, Nelder-Mead simplex is introduced to reinforce the intensification capacity of the algorithm. The effectiveness of CCNMSMA has been verified in a single diode model, double diode model, and three diode models for RTC France solar cell and PVM 752 GaAs cell. Three commercial PV module models, which are the ST40, SM55, and KC200GT, are also utilized to verify the stability of CNMSMA under various temperatures and irradiances. The simulation results demonstrate that a developed SMA-based method can accurately extract the unknown photovoltaic solar cells' unknown parameters and achieve excellent convergence rapidity and stability performance. Also, no matter under insufficient irradiance or high-temperature conditions, CNMSMA is still without losing its accuracy and shows satisfactory stability. Accordingly, the proposed algorithm could act as a reliable and developed tool for extracting significant unknown parameters of photovoltaic models. This research will be supported by https://aliasgharheidari.com. •An improved Slime Mound Algorithm (CNMSMA) is proposed to extract parameters of photovoltaic system.•Ten chaotic maps are combined with Nelder-Mead simplex to design a new optimizer CNMSMA.•CNMSMA were evaluated under different irradiance levels and temperature levels.•CNMSMA has better optimization performance and stabilikty than other competitive algorithms.