4.7 Article

Estimations of Global Horizontal Irradiance and Direct Normal Irradiance by Using Fengyun-4A Satellite Data in Northern China

Journal

REMOTE SENSING
Volume 13, Issue 4, Pages -

Publisher

MDPI
DOI: 10.3390/rs13040790

Keywords

FengYun-4A; surface solar irradiance; satellite image; McClear

Funding

  1. National Natural Science Foundation of China [41805085]
  2. Science and Technology Project of Gansu Province [20JR5RA544]
  3. Doctoral Research Fund of Lanzhou City University [LZCU-BS2019-13]

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Accurate solar radiation estimation is crucial for solar energy systems, with high-precision remote sensing data being used to fill the gap in surface radiation observations. This study tested a global solar irradiance estimation method using data from the FengYun-4A satellite, showing that the estimated global horizontal irradiance (GHI) was slightly affected by seasons, while direct normal irradiance (DNI) estimation was less accurate. A new DNI radiation algorithm during autumn and winter is proposed for northern China to improve accuracy.
Accurate solar radiation estimation is very important for solar energy systems and is a precondition of solar energy utilization. Due to the rapid development of new energy sources, the demand for surface solar radiation estimation and observation has grown. Due to the scarcity of surface radiation observations, high-precision remote sensing data are trying to fill this gap. In this paper, a global solar irradiance estimation method (in different months, seasons, and weather conditions), using data from the advanced geosynchronous radiation imager (AGRI) sensor onboard the FengYun-4A satellite with cloud index methodology (CSD-SI), was tested. It was found that the FengYun-4A satellite data could be used to calculate the clear sky index through the Heliosat-2 method. Combined with McClear, the global horizontal irradiance (GHI) and the direct normal irradiance (DNI) in northeast China could be accurately obtained. The estimated GHI accuracy under clear sky was slightly affected by the seasons and the normalized root mean square error (nRMSE) values (in four sites) were higher in summer and autumn (including all weather conditions). Compared to the estimated GHI, the estimated DNI was less accurate. It was found that the estimated DNI in October had the best performance. In the meantime, the nRMSE, the normalized mean absolute error (nMAE), and the normalized mean bias error (nMBE) of Zhangbei were 35.152%, 27.145%, and -8.283%, while for Chengde, they were 43.150%, 28.822%, and -13.017%, respectively. In addition, the estimated DNI at ground level was significantly higher than the actual observed value in autumn and winter. Considering that the error mainly came from the overestimation of McClear, a new DNI radiation algorithm during autumn and winter is proposed for northern China. After applying the new algorithm, the nRMSE decreased from 49.324% to 48.226% for Chengde and from 48.342% to 41.631% for Zhangbei. Similarly, the nMBE decreased from -32.351% to -18.823% for Zhangbei and from -26.211% to -9.107% for Chengde.

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