基于人工神经网络的光伏板硬遮阳建模与检测

Bryan E. Escoto
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引用次数: 1

摘要

由于光伏板表面的污垢堆积造成的硬遮阳,以及面板表面附近的建筑物、树木甚至不需要的材料造成的阴影,都会降低光伏板的性能,大大降低了输出功率和效率。然而,太阳能电池板遮阳的检测是一个复杂而具有挑战性的过程,因为太阳能电池板的功率转换是不同的,并且受太阳辐照度、温度、太阳位置、遮阳位置等多种因素的影响。该项目创建了一个人工神经网络(ANN)模型,用于检测硬阴影及其对光伏板的覆盖。本研究开发的最优人工神经网络模型可以以99.98%的准确率检测太阳能电池板的硬遮阳覆盖率。最佳的人工神经网络拓扑是3-60-1(输入-隐藏神经元-输出)模型,该模型具有良好的泛化能力。该模型在输入隐藏层和隐藏输出层都使用了tan Sigmoid传递函数,在优化过程中,Levenberg Marquardt优于其他算法。最优ANN模型在训练、验证、测试和总体上的MSE最低为0.000020333,r值最高为0.99992、0.99989、0.9999和0.99992。灵敏度分析结果表明,开路电压对太阳能板遮阳检测有显著影响。
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Modeling and Detection of PV Panel Hard Shading Using Artificial Neural Network
The hard shading caused by dirt accumulation on the PV surface, shadows caused by near structures, trees, and even unwanted materials at the surface of the panels degrades the performance of the PV panels, significantly reducing the power output and its efficiency. However, the detection of shading of the solar panel is a complex and challenging process since the panel's power conversion varies and is affected by several factors such as solar irradiance, temperature, the position of the sun, location of shading, etc. This project created an Artificial Neural Network (ANN) model that detects the hard shading and its coverage to PV panels. The optimum ANN model developed in this study can detect solar panel hard shading coverage with 99.98 % accuracy. The best ANN network topology is 3-60-1 (input-hidden neurons-output) model which provides an excellent generalization ability. This model utilized the tan Sigmoid transfer function for both input-hidden and hidden-output layer, and for the optimization process, Levenberg Marquardt outperformed other algorithms. The optimum ANN model has the lowest MSE value of 0.000020333 and with highest R-values of 0.99992, 0.99989, 0.9999, and 0.99992 for training, validation, testing, and overall, respectively. Based on the sensitivity analysis result, the open-circuit voltage significantly contributes to the solar panel shading detection.
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