Abstract

Clear-sky detection (CSD) is of critical importance in solar energy applications and surface radiative budget studies. Existing CSD methods are not sufficiently validated due to the lack of high-temporal resolution and long-term CSD ground observations, especially at polluted sites. Using five-year high resolution ground-based solar radiation data and visual inspected Total Sky Imager (TSI) measurements at polluted Xianghe, a suburban site, this study validated 17 existing CSD methods and developed a new CSD model based on a machine-learning algorithm (Random Forest: RF). The propagation of systematic errors from input data to the calculated global horizontal irradiance (GHI) is confirmed with Mean Absolute Error (MAE) increased by 99.7% (from 20.00 to 39.93 W·m−2). Through qualitative evaluation, the novel Bright-Sun method outperforms the other traditional CSD methods at Xianghe site, with high accuracy score 0.73 and 0.92 under clear and cloudy conditions, respectively. The RF CSD model developed by one-year irradiance and TSI data shows more robust performance, with clear/cloudy-sky accuracy score of 0.78/0.88. Overall, the Bright-Sun and RF CSD models perform satisfactorily at heavy polluted sites. Further analysis shows the RF CSD model built with only GHI-related parameters can still achieve a mean accuracy score of 0.81, which indicates RF CSD models have the potential in dealing with sites only providing GHI observations.

Highlights

  • Surface irradiance is vital in many different fields such as agriculture, atmospheric science, building design and engineering [1]

  • 1b, we found a good correlation of MERRA-2 and with the a good correlation of MERRA-2 and AERONET precipitable water vapor (PWV) with the values of R, Root Mean Square Error (RMSE), values of 0.97, R2, RMSE, Mean Absolute Error (MAE)

  • Regarding to the conventional CSDsky methods except Bright-Sun, higher clear-sky accuracy score often associates with lower cloudy-sky accuracy score, and vice versa

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Summary

Introduction

Surface irradiance is vital in many different fields such as agriculture, atmospheric science, building design and engineering [1]. Clouds are a major modulator of surface irradiance causing dramatic difference from a clear-sky counterpart, based on which clearsky detection (CSD) methods on 1 min irradiance time series are developed (i.e., Gueymard et al [2] and references therein). These CSD methods typically adopt global horizontal irradiance (GHI), and sometimes direct normal irradiance (DNI) or diffuse horizontal irradiance (DHI) [3,4,5] to build linear classifiers in nature across the boundary of cloudy and clear skies. Bright et al [7] proposed a novel and globally applicable

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