Evaluation of Himawari-8 surface downwelling solar radiation by ground-based measurements

Damiani, Alessandro; Irie, Hitoshi; Horio, Takashi; Takamura, Toshinari; Khatri, Pradeep; Takenaka, Hiroyuki; Nagao, Taro; Nakajima, Takashi Y.; Cordero, Raúl R.

doi:10.5194/amt-11-2501-2018

Cited by 62 publications

(33 citation statements)

References 66 publications

(113 reference statements)

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“…Aerosol information (e.g., optical depth of aerosol) has not been considered in the current satellite algorithms for surface GHI value (see Section 2.2). For further verification of satellite-derived GHI values using surface GHI observations, see the previous publication by Damiani et al [24].…”

Section: A Case Study Of Cumulus Cloud Simulationmentioning

confidence: 87%

“…AMATERASS datasets from Himawari-8 were also used to validate spatial distributions in GHI model simulations. Validation of the satellite-derived GHI data with ground-based data resulted in a mean bias error (MBE) within the range of 20-30 W m −2 under all-sky conditions (10-15 W m −2 under clear-sky conditions) and a root mean square error (RMSE) of approximately 80 W m −2 (Damiani et al [24]).…”

Section: Satellite-derived Solar Irradiancementioning

confidence: 99%

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Solar Irradiance Forecasts by Mesoscale Numerical Weather Prediction Models with Different Horizontal Resolutions

et al. 2019

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This study examines the performance of radiation processes (shortwave and longwave radiations) using numerical weather prediction models (NWPs). NWP were calculated using four different horizontal resolutions (5, 2 and 1 km, and 500 m). Validation results on solar irradiance simulations with a horizontal resolution of 500 m indicated positive biases for direct normal irradiance dominate for the period from 09 JST (Japan Standard Time) to 15 JST. On the other hand, after 15 JST, negative biases were found. For diffused irradiance, weak negative biases were found. Validation results on upward longwave radiation found systematic negative biases of surface temperature (corresponding to approximately −2 K for summer and approximately −1 K for winter). Downward longwave radiation tended to be weak negative biases during both summer and winter. Frequency of solar irradiance suggested that the frequency of rapid variations of solar irradiance (ramp rates) from the NWP were less than those observed. Generally, GHI distributions between the four different horizontal resolutions resembled each other, although horizontal resolutions also became finer.

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Section: A Case Study Of Cumulus Cloud Simulationmentioning

confidence: 87%

Section: Satellite-derived Solar Irradiancementioning

confidence: 99%

Solar Irradiance Forecasts by Mesoscale Numerical Weather Prediction Models with Different Horizontal Resolutions

et al. 2019

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“…The Advanced Himawari Imagers aboard the Himawari-8 acquire full-disk observations in 16 bands (three for visible, three for NIR, and 10 for infrared wavelengths) every 10 min (and over Japan, every 2.5 min), with a spatial resolution ranging from 0.5 km to 2.0 km (Bessho et al, 2016;Damiani et al, 2018). Using the EXAM algorithm, one can leverage these observations to estimate surface downwelling global shortwave radiation over Japan at a 2.5-min temporal resolution and a nominal 1-km spatial resolution (Takenaka et al, 2011;Damiani et al, 2018). In this study, we used a solar radiation dataset with a 30-min temporal resolution.…”

Section: Solar Radiation Datamentioning

confidence: 99%

Improving the UAV-based yield estimation of paddy rice by using the solar radiation of geostationary satellite Himawari-8

Hama

Tanaka²,

Tsuruoka

et al. 2020

Hydrological Research Letters

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The objectives of this study were to improve the yield estimation of paddy rice based on the unmanned aerial vehicle remote sensing (UAV-RS) and solar radiation data sets. The study used the UAV-RS-based normalized difference vegetation index (NDVI) at the heading stage, the solar radiation data of geostationary satellite Himawari-8 and the solar radiation data of polar orbiting satellite Aqua/ MODIS. A comparison of two satellite-based solar radiation data sets (Himawari-8 and MODIS PAR) showed that the coefficient of determination (R 2 ) of estimated yield based on Himawari-8 solar radiation was 0.7606 while the R 2 of estimated yield based on the MODIS PAR was 0.4749. Additionally, the root mean square error (RMSE) of Himawari-8 solar radiation was 26.5 g/m 2 while the RMSE of estimated yield based on the MODIS PAR was 39.2 g/m 2 (The average observed yield was 489.3 g/m 2 ). The Estimated yield based on Himawari-8 solar radiation, therefore, outperformed the MODIS PAR-based estimated yield. The improvement of the temporal resolution of the satellite-based dataset allowed by using the Himawari-8 data set contributed to the improvement of estimation accuracy. Satellite-based solar radiation data allow yield estimation based on remote sensing in regions where there are no ground observation data of solar radiation.

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“…Errors in satellite-based data have been observed in some previous studies [10] Smart Grid and Renewable Energy [11] [12]. The difference between measured irradiance and that derived from Himawari-8, a Japanese stationary weather satellite, has been evaluated [10]. Although the accuracy of estimation based on Himawari-8 observation has improved compared to the estimation based on Himawari-7, problems such as the influence of albedo and radiation enhancement have remained.…”

Section: Error In Satellite Datamentioning

confidence: 99%

A Method for the Detection of Decrease in Power in PV Systems Using Satellite Data

Kawasaki¹,

Okajima²

2019

SGRE

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In this paper, a method to detect a decrease in the output power of photovoltaic systems is proposed. This method is based on using satellite irradiance data. In addition, fault detection is carried out with only one day's data in this method. Thus, the time elapses since the decrease in output is shorter than with the other methods. In order to mitigate the error in satellite data and improve the accuracy of fault detection, data extraction is carried out, which consists of two steps. In the first step, effective data are extracted by setting a lower irradiance limit. In the second step, "Calculation day" is determined depending on the number of effective data in one day. Fault detection, which is only conducted on the Calculation day, is conducted by comparing the expected power and the measured power. The parameters used in this study were optimized by testing 45 systems that appear normal. Subsequently, 340 systems were analyzed with the proposed method, using optimized parameters. The results showed the effectiveness of our method from the viewpoints of both accuracy and time required. In addition, three data extraction methods were considered to distinguish between the permanent decrease caused by failure, and the temporary decrease caused by partial shade. Fuzzy cluster analysis showed the best result among the three methods used.

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Evaluation of Himawari-8 surface downwelling solar radiation by ground-based measurements

Cited by 62 publications

References 66 publications

Solar Irradiance Forecasts by Mesoscale Numerical Weather Prediction Models with Different Horizontal Resolutions

Solar Irradiance Forecasts by Mesoscale Numerical Weather Prediction Models with Different Horizontal Resolutions

Improving the UAV-based yield estimation of paddy rice by using the solar radiation of geostationary satellite Himawari-8

A Method for the Detection of Decrease in Power in PV Systems Using Satellite Data

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