Parameters extraction of photovoltaic cells using swarm intelligence based optimization technique: research on single diode model and double diode model

IF 0.6 Q3 ENGINEERING, MULTIDISCIPLINARY Mehran University Research Journal of Engineering and Technology Pub Date : 2023-04-03 DOI:10.22581/muet1982.2302.17
Muhammad Imran Ghoto, Mazhar Hussain Balouch, Touqeer Ahmed Jummani, A. A. Memon
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Abstract

Solar-energy is a clean source of energy and photovoltaic (PV) panels are constructed from solar cells (SC) which convert energy of light into electricity without any environmental effect. The researchers and policy makers focus on the huge scale adoption of solar panels due to its cleaner production. However, there is non-linear behavior in current-voltage characteristics of solar panels and shortage of data in manufacturer’s datasheet. In order to enhance the efficiency of solar panels it is mandatory to develop the PV panels scheme accurately by extracting the basic parameters. In this research study a mathematical model of two different solar cell models is used such as Single Diode Model (SDM) and Double Diode Model (DDM). The Particle Swarm Optimization (PSO) is used to extract the five and seven unknown parameters of SDM and DDM. The algorithm runs with one thousand iterations to minimize the Root Mean Square Error (RMSE) where the RMSE is the vector of five unknown parameters for SDM and seven    for DDM. The superiority of proposed PSO algorithm is proved by the optimized results of unrevealed parameters with minimized RMSE of up to 10-3. Optimum parameter values for the solar cell models are applied on the real time data of a 55 mm diameter commercial RTC-France SC. Finally, the results reveal that P-V and I-V curves exhibit smallest deviation between estimated and real time values. The results reveal that the proposed PSO converges to optimal solution with least number of iterations compared to the existing metaheuristic algorithms.
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基于群智能优化技术的光伏电池参数提取:单二极管模型和双二极管模型研究
太阳能是一种清洁能源,光伏(PV)板是由太阳能电池(SC)制成的,它将光能转化为电能,而不会对环境产生任何影响。研究人员和政策制定者将重点放在太阳能电池板的大规模采用上,因为它的生产更清洁。然而,太阳能电池板的电流电压特性存在非线性行为,且制造商的数据表缺乏数据。为了提高太阳能电池板的效率,必须通过提取基本参数来准确地制定太阳能电池板方案。本研究采用了单二极管模型(SDM)和双二极管模型(DDM)两种不同的太阳能电池模型的数学模型。采用粒子群算法分别提取SDM和DDM的5个和7个未知参数。该算法运行一千次迭代,以最小化均方根误差(RMSE),其中RMSE是SDM的五个未知参数的向量,DDM的七个未知参数的向量。未显示参数的优化结果证明了该算法的优越性,RMSE最小值可达10-3。将模型的最佳参数值应用于直径为55 mm的商用RTC-France SC的实时数据,结果表明,P-V和I-V曲线与实时值之间的偏差最小。结果表明,与现有的元启发式算法相比,该算法收敛到迭代次数最少的最优解。
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发文量
76
审稿时长
40 weeks
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