利用卫星图像和神经网络建立PV输出变异性模型

M. Reno, J. Stein
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引用次数: 5

摘要

在地面上测量到的高频辐照度变化是由天空中云的形成、消散和通过引起的。随着光伏渗透水平的提高,光伏系统的可变性和斜坡率对于理解和建立电网稳定性模型越来越重要。利用卫星图像识别云的类型和模式可以预测缺乏传感器地区的辐照度变化。卫星图像覆盖了整个美国,这使得更准确的整合规划和大范围的潮流建模成为可能。在一年的时间里,每隔15分钟分析一次内华达州南部的卫星图像。开发并测试了图像稳定、云检测和云的纹理分类方法。高性能计算并行处理算法也进行了研究和测试。使用图像作为输入的人工神经网络在基于地面的辐照度测量上进行了训练,以模拟可变性,并进行了测试,显示出作为预测辐照度可变性手段的一些希望。人工神经网络、云纹理分析和云类型分类可以用来模拟一个位置的一分钟分辨率的辐照度和可变性,而不需要许多地面辐照度传感器。
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PV output variability modeling using satellite imagery and neural networks
High frequency irradiance variability measured on the ground is caused by the formation, dissipation, and passage of clouds in the sky. Variability and ramp rates of PV systems are increasingly important to understand and model for grid stability as PV penetration levels rise. Using satellite imagery to identify cloud types and patterns can predict irradiance variability in areas lacking sensors. With satellite imagery covering the entire U.S., this allows for more accurate integration planning and power flow modelling over wide areas. Satellite imagery from southern Nevada was analyzed at 15 minute intervals over a year. Methods for image stabilization, cloud detection, and textural classification of clouds were developed and tested. High Performance Computing parallel processing algorithms were also investigated and tested. Artificial Neural Networks using imagery as inputs were trained on ground-based measurements of irradiance to model the variability and were tested to show some promise as a means for predicting irradiance variability. Artificial Neural Networks, cloud texture analysis, and cloud type categorization can be used to model the irradiance and variability for a location at a one minute resolution without needing many ground based irradiance sensors.
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