Abstract

Solar energy production is affected by the attenuation of incoming irradiance from underlying clouds. Often, improvements in the short-term predictability of irradiance using satellite irradiance models can assist grid operators in managing intermittent solar-generated electricity. In this paper, we develop and test a satellite irradiance model with short-term prediction capabilities using cloud motion vectors. Near-real time visible images from Himawari-8 satellite are used to derive cloud motion vectors using optical flow estimation techniques. The cloud motion vectors are used for the advection of pixels at future time horizons for predictions of irradiance at the surface. Firstly, the pixels are converted to cloud index using the historical satellite data accounting for clear, cloudy and cloud shadow pixels. Secondly, the cloud index is mapped to the clear sky index using a historical fitting function from the respective sites. Thirdly, the predicated all-sky irradiance is derived by scaling the clear sky irradiance with a clear sky index. Finally, a power conversion model trained at each site converts irradiance to power. The prediction of solar power tested at four sites in Australia using a one-month benchmark period with 5 min ahead prediction showed that errors were less than 10% at almost 34–60% of predicted times, decreasing to 18–26% of times under live predictions, but it outperformed persistence by >50% of the days with errors <10% for all sites. Results show that increased latency in satellite images and errors resulting from the conversion of cloud index to irradiance and power can significantly affect the forecasts.

Highlights

  • This paper evaluates the performance of short-term power forecasts produced from the Satellite Irradiance Forecasting Model (SIFM) using near real-time Himawari-8 satellite images at four solar power farms located in Australia

  • The downwelling solar irradiance was converted to power forecasts using a power conversion model

  • global horizontal irradiance (GHI) forecasts produced errors with normalized root mean square error (nRMSE) ranging from 19–35%

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Summary

Introduction

Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. The uptake of solar energy in the global renewable energy mix has been rampant. The global solar capacity has reached to levels at par with global wind capacity, each accounting for 26% of global renewable energy generation capacity [1]. In Australia, solar power contributed to 6% of total electricity generation in 2018–2019 with largest growth in large-scale solar power generations [2]. A rapid decline in costs associated with solar installations are driving the uptake of solar energy across the globe [3], including Australia [4]

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