Shadow-camera based solar nowcasting system for shortest-term forecasts

Shadow-camera based solar nowcasting system for shortest-term forecasts

The rapid growth of solar power generation and the variable nature of the solar resource pose challenges for our electricity grids. Forecasting future changes in the irradiance might help to cost-efficiently manage this variability both for photovoltaic and concentration solar plants as well as grid...

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Main Authors: Pascal Kuhn, Dominik Garsche, Stefan Wilbert, Bijan Nouri, Natalie Hanrieder, Christoph Prahl, Luis Zarzarlejo, Jesús Fernández, Andreas Kazantzidis, Thomas Schmidt, Detlev Heinemann, Philippe Blanc, Robert Pitz-Paal
Format: Article
Language:English
Published: Borntraeger 2019-10-01
Series:Meteorologische Zeitschrift
Subjects:
solar nowcasting
energy meteorology
meteorological cameras
forecasting
Online Access:http://dx.doi.org/10.1127/metz/2019/0954
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spelling doaj-7cb708586bb341d9aea958a305f573d92020-11-25T01:37:01ZengBorntraegerMeteorologische Zeitschrift0941-29482019-10-0128325527010.1127/metz/2019/095491154Shadow-camera based solar nowcasting system for shortest-term forecastsPascal KuhnDominik GarscheStefan WilbertBijan NouriNatalie HanriederChristoph PrahlLuis ZarzarlejoJesús FernándezAndreas KazantzidisThomas SchmidtDetlev HeinemannPhilippe BlancRobert Pitz-PaalThe rapid growth of solar power generation and the variable nature of the solar resource pose challenges for our electricity grids. Forecasting future changes in the irradiance might help to cost-efficiently manage this variability both for photovoltaic and concentration solar plants as well as grids with high solar penetrations. So far, for shortest-term forecasts with lead times of a few minutes, all-sky imager based nowcasting systems are used. However, due to the complexity of dynamically changing 3d cloud shapes as well as certain geometrical effects such as self-occlusion or near-horizon saturation, all-sky imager based nowcasting systems exhibit inherent weaknesses. Here, we present a novel system to generate shortest-term solar forecasts, which is located at Plataforma Solar de Almería in southern Spain. This approach is based on downward-facing cameras (shadow cameras), taking images of the ground. From these images, spatially resolved irradiance maps are derived. By tracking cloud shadows, future irradiances are predicted. A demonstration system is achieved, which provides shortest-term forecasts for the next 2 min. To the best of our knowledge, this is the first time such a system is developed. We benchmark several possible algorithmic approaches on 16 days and compare the deviations to a state-of-the-art all-sky imager based nowcasting system on 22 days. The root-mean-squared deviation (RMSD) of this shadow camera based nowcasting system for direct normal irradiance (DNI) and 1‑min temporal averages is 15.6 % for lead times of 2 min (MAD, DNI: 9.6 %). In comparison to an all-sky imager system, this is an improvement as the all-sky imager system only reaches 22.0 % RMSD and 14.8 % MAD (both DNI). This demonstrates the feasibility and attractiveness in terms of accuracy of the proposed concept.http://dx.doi.org/10.1127/metz/2019/0954solar nowcastingenergy meteorologymeteorological camerasforecasting
collection DOAJ
language English
format Article
sources DOAJ
author Pascal Kuhn
Dominik Garsche
Stefan Wilbert
Bijan Nouri
Natalie Hanrieder
Christoph Prahl
Luis Zarzarlejo
Jesús Fernández
Andreas Kazantzidis
Thomas Schmidt
Detlev Heinemann
Philippe Blanc
Robert Pitz-Paal
spellingShingle Pascal Kuhn
Dominik Garsche
Stefan Wilbert
Bijan Nouri
Natalie Hanrieder
Christoph Prahl
Luis Zarzarlejo
Jesús Fernández
Andreas Kazantzidis
Thomas Schmidt
Detlev Heinemann
Philippe Blanc
Robert Pitz-Paal
Shadow-camera based solar nowcasting system for shortest-term forecasts
Meteorologische Zeitschrift
solar nowcasting
energy meteorology
meteorological cameras
forecasting
author_facet Pascal Kuhn
Dominik Garsche
Stefan Wilbert
Bijan Nouri
Natalie Hanrieder
Christoph Prahl
Luis Zarzarlejo
Jesús Fernández
Andreas Kazantzidis
Thomas Schmidt
Detlev Heinemann
Philippe Blanc
Robert Pitz-Paal
author_sort Pascal Kuhn
title Shadow-camera based solar nowcasting system for shortest-term forecasts
title_short Shadow-camera based solar nowcasting system for shortest-term forecasts
title_full Shadow-camera based solar nowcasting system for shortest-term forecasts
title_fullStr Shadow-camera based solar nowcasting system for shortest-term forecasts
title_full_unstemmed Shadow-camera based solar nowcasting system for shortest-term forecasts
title_sort shadow-camera based solar nowcasting system for shortest-term forecasts
publisher Borntraeger
series Meteorologische Zeitschrift
issn 0941-2948
publishDate 2019-10-01
description The rapid growth of solar power generation and the variable nature of the solar resource pose challenges for our electricity grids. Forecasting future changes in the irradiance might help to cost-efficiently manage this variability both for photovoltaic and concentration solar plants as well as grids with high solar penetrations. So far, for shortest-term forecasts with lead times of a few minutes, all-sky imager based nowcasting systems are used. However, due to the complexity of dynamically changing 3d cloud shapes as well as certain geometrical effects such as self-occlusion or near-horizon saturation, all-sky imager based nowcasting systems exhibit inherent weaknesses. Here, we present a novel system to generate shortest-term solar forecasts, which is located at Plataforma Solar de Almería in southern Spain. This approach is based on downward-facing cameras (shadow cameras), taking images of the ground. From these images, spatially resolved irradiance maps are derived. By tracking cloud shadows, future irradiances are predicted. A demonstration system is achieved, which provides shortest-term forecasts for the next 2 min. To the best of our knowledge, this is the first time such a system is developed. We benchmark several possible algorithmic approaches on 16 days and compare the deviations to a state-of-the-art all-sky imager based nowcasting system on 22 days. The root-mean-squared deviation (RMSD) of this shadow camera based nowcasting system for direct normal irradiance (DNI) and 1‑min temporal averages is 15.6 % for lead times of 2 min (MAD, DNI: 9.6 %). In comparison to an all-sky imager system, this is an improvement as the all-sky imager system only reaches 22.0 % RMSD and 14.8 % MAD (both DNI). This demonstrates the feasibility and attractiveness in terms of accuracy of the proposed concept.
topic solar nowcasting
energy meteorology
meteorological cameras
forecasting
url http://dx.doi.org/10.1127/metz/2019/0954
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