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The CAMS Radiation Service is designed to meet the requirements that have been specified for the Copernicus Atmosphere Monitoring Service (CAMS). The precursor projects MACC and MACC-II/-III prepared the CAMS Radiation Service in terms of implementation, sustained operation and availability. It was ensured that the service lines have been designed to best meet both the requirements of downstream service providers and end users at the European, national and local levels, and the requirements of the global scientific user community. This page provides a high level overview of the solar radiation service products; more details can be found in the Section Detailed documentation.
The CAMS solar radiation services (CRS) provide historical values (2004 to present) of global (GHI), direct (BHI) and diffuse (DHI) solar irradiation, as well as direct normal irradiation (BNI). The aim is to fulfil the needs of European and national policy development and the requirements of both commercial and public downstream services, e.g. for planning, monitoring, efficiency improvements and the integration of solar energy systems into energy supply grids.
For clear-sky conditions, an irradiation time series is provided for any location in the world using information on aerosol, ozone and water vapour from the CAMS global forecasting system. Other properties, such as ground albedo and ground elevation, are also taken into account.
Similar time series are available for all-sky conditions including cloudy situations but, since the high-resolution cloud information is directly inferred from satellite observations, these are currently only available inside the field-of-view of the Meteosat Second Generation 0-deg satellite, which is roughly Europe, Africa, the Middle East, the Atlantic Ocean and Brazil, and the HIMAWARI satellite, which is roughly east of Asia and Oceania.
A gridded all-sky dataset for the satellite field of view is made available as well. It consists of a collection of times series on a regular latitude/longitude grid and re-packed to a monthly gridded dataset. This product is meant to fulfill user needs e.g. from energy system analysis modelers. It is currently only available inside the field-of-view of the Meteosat Second Generation 0-deg satellite.
Input quality control, regular quarterly benchmarking against ground stations, and regular monitoring the consistency and detecting possible trends is performed.
A detailed User Guide is available here: User Guide to the CAMS Radiation Service (CRS)
Validation reports are made on a quarterly basis every three months. They include quarterly and also once a year multi-annual statistics at worldwide stations against ground observations of irradiation. These reports are made routinely available on the CAMS web page.
There are time series (CRS-TIME) data for a given point available as well as a gridded solar radiation dataset (CRS-GRID) over Europe and Africa (land only). This gridded data set is a collection of time series on a chosen latitude/longitude grid and re-packed to monthly files.
Time series data (CRS-TIME) for a given point is offered via the Copernicus Atmosphere Data Store (ADS) in both ASCII and NetCDF format.
Additionally, an ASCII "expert mode" format can be selected which contains in addition to the irradiation, all the input data used in their calculation (aerosol optical properties, water vapour concentration, etc). This additional information is only meaningful in the time frame at which the calculation is performed and so is only available at 1-minute time steps in universal time (UT).
Table 1: Overview of key characteristics of CRS-TIME products.
| CRS-TIME Clear-Sky (McClear method) | CRS-TIME All-Sky (Heliosat-4 method) |
ADS name | Cloud-free conditions only | Both cloud-free and actual weather conditions |
Type of product | Point data, time-series | |
Parameters | GHI, DHI, BHI, BNI | |
Geographical area | global | Europe / Africa / Middle East / Atlantic Ocean / Brazil / east of Asia / Oceania |
Horizontal resolution | Interpolated to point of interest from various spatial input data resolutions | |
Time coverage | from 2004-01-01 to | from 2004-02-01 for Meteosat and 2016-01-01 for Himawari field of view |
Temporal resolution | 1 min, 15 min, 1 h, 1 day, 1 month | |
Data format | ASCII (CSV), NetCDF | |
Data file size | File size depends on the temporal resolution. Largest files are in 1 min temporal resolution and the CSV data format | |
Data access | Atmosphere Data Store, , the number of requests is limited to 100 per day. Users are invited to discuss their additional needs with the Copernicus Help Desk individually. | |
Processing | on request; data normally available within a few minutes | |
Update of the databases | 2 days delayed mode |
The CAMS Radiation Service CSV formatted times series products (CRS-TIME) are presented as a metadata header section, followed by lines of values (columns). The metadata header section helps the user to understand the data, and describing the various features of the products. These metadata are written as text in the delivered file, and conform to the ISO standard where available. Currently these metadata are:
Each line corresponds to an instance of output observation data for a given period. The typical content of a line is:
The exact content of a line depends on the type of product and the description is provided in the metadata. This is why metadata are included in the file header as plain text.
The gridded solar radiation dataset (CRS-GRID) is available via the Copernicus Atmosphere Data Store (ADS) in NetCDF format. It is a pre-processed collection of CRS v4.5 time series every 0.1° on a regular latitude and longitude grid in the Meteosat Second Generation field of view and for the 15 min temporal resolution. This group of time series was converted into monthly NetCDF files. The expert mode variables do not exist for CRS-GRID.
Table 2: Overview of key characteristics of CRS-GRID data.
| CAMS all-sky and clear sky (CRS-GRID) |
Type of product | Gridded data |
Parameters | GHI, DHI, BHI, BNI |
Geographical area | Europe / Africa / Middle East / Atlantic Ocean / Brazil, land and coastal areas only |
Horizontal resolution | 0.1° in latitude and longitude |
Time coverage | from 2005-01-01 to |
Temporal resolution | 15 min |
Data format | Monthly NetCDF files |
Data file size | depending on region |
Data access | |
Processing | Pre-processed with CRS version 4.5 |
Update of the databases | On an annual basis |
Main Variable Names | NetCDF Units | Description |
---|---|---|
BHI | Wh m-2 | All-sky direct (beam) irradiation, i.e., the direct part of the surface solar downward irradiation integrated over the whole spectrum available at ground level, on a horizontal surface. For cloudy atmospheres, both non-scattered and scattered radiation within the field-of-view of a pyrheliometer are taken into account. |
BNI | Wh m-2 | All-sky Direct Normal Irradiation. Part of the radiation that is received from the direction of the sun by a plane facing the sun. For cloudy atmospheres, both non-scattered and scattered radiation within the field-of-view of a pyrheliometer are taken into account. |
DHI | Wh m-2 | All-sky diffuse irradiation, i.e., the diffuse part of the surface solar downward irradiation integrated over the whole spectrum available at ground level, on a horizontal surface |
GHI | Wh m-2 | All-sky global irradiation, i.e., the surface solar downward irradiation integrated over the whole spectrum available at ground level, on a horizontal surface |
BHIc | Wh m-2 | Direct horizontal clear sky irradiation |
BNIc | Wh m-2 | Direct normal clear sky irradiation |
DHIc | Wh m-2 | Diffuse horizontal clear sky irradiation |
GHIc | Wh m-2 | Global horizontal clear sky irradiation |
For expert users, all input and output variables are provided in the ‘detailed info expert output mode’ available as part of the time series service (CRS-TIME). It can only be retrieved when requesting 1 min resolved time series from the Atmosphere Data Store. Besides the standard outputs, it provides:
Users may:
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Note should be taken that the content of the detailed info mode may change depending on the version of Heliosat‑4 or McClear. Each product contains a detailed description of its content and the user should refer to it. |
Date | Version | Description |
2023-10 | v4.6 (current) | Access to Himawari satellite field of view now online. New error messages for CAMS Radiation and McClear services. |
2023-07 | v4.6 | New improved version of CAMS Radiation Service all sky model. This version 4.6 uses the new version 48r1 of CAMS IFS numerical weather introduced on 2023-06-27 in McClear v3.6. Data prior to 2023-06-27 are unchanged. A new column SOAOD550 has been added to the csv output format of the expert mode. Bug fix in CAMS Radiation Service gap filling at sunset/sunrise. Bug in CAMS Radiation Service cloud type: cloud free instances were marked as low level clouds, now it is corrected to type 0. |
2022-09 | v4.5 | New version of the all-sky model. Version 4.5 uses a new clear sky model (McClear 3.5) and no bias correction anymore. The clear-sky model McClear 3.5 uses now the CAMS Reanalysis for 2004-2020. |
2021-06 | v4.0 | Since 2013, CAMS Radiation service used the cloud retrieval scheme APOLLO. The version 4.0 of CAMS Radiation Service includes a new version APOLLO Next Generation (APOLLO_NG) that improves cloud detection using fuzzy logic. New McClear v3.5 version using CAMS IFS reanalysis data. Fix in the MSG satellite projection handling for all data before 12/2017. A new global bias correction was implemented. |
2018-06 | v3.2 | Fix of a mathematical bug in the (latitude, longitude) position of the pixels of the Meteosat satellite images. |
2018-03 | v3.1 | CAMS McClear benefits from the successive enhancements of the Aerosol Optical Depth versions. McClear version, and consequently CAMS radiation service version as well, have been incremented from 3.0 to 3.1. Results are slightly modified in October 2012 and September-November 2015. |
2017-10 | v3 | McClear clear sky model v3 |
2015-10 | v2.7 | McClear v2.7 |
2015-07 | v2.6 | Bug fixed in verbose expert mode |
2015-02 | v2.6 | Bug fixed in the filling of MACC AOD databases |
2015-01 | v2.6 | Bug fixed bug for cloud coverage > 100% |
2014-11 | v2.5 | APOLLO data coverage extension: 2004-02-01 to D-2 |
2014-11 | v2.4 | Call to McClear v2.4 |
2014-08 | v2.3 | Call to McClear v2.3 Bug fixed in APOLLO data interpolation |
v2.2 | does not exist (synchronization with McClear versions) | |
2014-07 | v2.1 | Bug fixed for the shift of one pixel in APOLLO files import |
2013-07 | v2.0 | Edition format file version 1 |
The use of the CAMS Radiation Service data should be acknowledged as indicated below:
All users of data uploaded from the Atmosphere Data Store (ADS) shall:
(1) provide clear and visible attribution to the Copernicus programme by citing the web catalogue page:
CAMS solar radiation time-series. Copernicus Atmosphere Monitoring Service (CAMS) Atmosphere Data Store (ADS). (Accessed on DD-MMM-YYY), https://ads.atmosphere.copernicus.eu/cdsapp#!/dataset/cams-solar-radiation-timeseries?tab=overview
or
CAMS gridded solar radiation. Copernicus Atmosphere Monitoring Service (CAMS) Atmosphere Data Store (ADS). (Accessed on DD-MMM-YYY), https://ads-dev.copernicus-atmosphere.eu/cdsapp#!/dataset/cams-solar-radiation-gridded?tab=overview
(2) acknowledge according to the data licence (i.e. licence to use Copernicus products (Clause 5 in particular)
(3) Cite the relevant peer-review publications for the the CAMS-Radiation Service:
Schroedter-Homscheidt, M., Azam, F., Betcke, J., Hanrieder, N., Lefèvre, M., Saboret, L., Saint-Drenan, Y.-M.: Surface solar irradiation retrieval from MSG/SEVIRI based on APOLLO Next Generation and HELIOSAT-4 methods, Contrib. Atm. Sci./Meteorol. Z.,2022, doi:10.1127/metz/2022/1132.
and
Qu, Z., Oumbe, A., Blanc, P., Espinar, B., Gesell, G., Gschwind, B., Klüser, L., Lefèvre, M., Saboret, L., Schroedter-Homscheidt, M., and Wald L.: Fast radiative transfer parameterisation for assessing the surface solar irradiance: The Heliosat-4 method, Meteorol. Z., 26, 33-57, doi: 10.1127/metz/2016/0781,2017. Available for download at https://www.schweizerbart.de/papers/metz/detail/26/87036/Fast_radiative_transfer_parameterisation_for_asses?af=crossref.
and for the CAMS clear-sky time series:
Gschwind, B., Wald L., Blanc, P., Lefèvre, M., Schroedter-Homscheidt, M., Arola, A., 2019. Improving the McClear model estimating the downwelling solar radiation at ground level in cloud free conditions – McClear-V3., Meteorol. Z./Contrib. Atm. Sci., 28, 2, 147-163, doi:10.1127/metz/2019/0946. Available for download at https://www.schweizerbart.de/papers/metz/detail/28/90593/Improving_the_McClear_model_estimating_the_downwelling_solar_radiation_at_ground_level_in_cloud_free_conditions_McClear_v3
and
Lefèvre, M., Oumbe, A., Blanc, P., Espinar, B., Gschwind, B., Qu, Z., Wald, L., Schroedter-Homscheidt, M., Hoyer-Klick, C., Arola, A., Benedetti, A., Kaiser, J., W., and Morcrette, J.-J.: McClear: a new model estimating downwelling solar radiation at ground level in clear-sky conditions, Atmos. Meas. Tech., 6, 2403–2418, doi: 10.5194/amt-6-2403-2013, 2013. Available for download at http://www.atmos-meas-tech.net/6/2403/2013/amt-6-2403-2013.pdf
Gschwind, B., Wald L., Blanc, P., Lefèvre, M., Schroedter-Homscheidt, M., Arola, A., 2019. Improving the McClear model estimating the downwelling solar radiation at ground level in cloud free conditions – McClear-V3., Meteorol. Z./Contrib. Atm. Sci., 28, 2, 147-163, doi:10.1127/metz/2019/0946. Available for download at https://www.schweizerbart.de/papers/metz/detail/28/90593/Improving_the_McClear_model_estimating_the_downwelling_solar_radiation_at_ground_level_in_cloud_free_conditions_McClear_v3
Lefèvre, M., Oumbe, A., Blanc, P., Espinar, B., Gschwind, B., Qu, Z., Wald, L., Schroedter-Homscheidt, M., Hoyer-Klick, C., Arola, A., Benedetti, A., Kaiser, J., W., and Morcrette, J.-J.: McClear: a new model estimating downwelling solar radiation at ground level in clear-sky conditions, Atmos. Meas. Tech., 6, 2403–2418, doi: 10.5194/amt-6-2403-2013, 2013. Available for download at http://www.atmos-meas-tech.net/6/2403/2013/amt-6-2403-2013.pdf
Qu, Z., Oumbe, A., Blanc, P., Espinar, B., Gesell, G., Gschwind, B., Klüser, L., Lefèvre, M., Saboret, L., Schroedter-Homscheidt, M., and Wald L.: Fast radiative transfer parameterisation for assessing the surface solar irradiance: The Heliosat-4 method, Meteorol. Z., 26, 33-57, doi: 10.1127/metz/2016/0781,2017. Available for download at https://www.schweizerbart.de/papers/metz/detail/26/87036/Fast_radiative_transfer_parameterisation_for_asses?af=crossref.
Schroedter-Homscheidt, M., Azam, F., Betcke, J., Hanrieder, N., Lefèvre, M., Saboret, L., Saint-Drenan, Y.-M.: Surface solar irradiation retrieval from MSG/SEVIRI based on APOLLO Next Generation and HELIOSAT-4 methods, Contrib. Atm. Sci./Meteorol. Z.,2022, doi:10.1127/metz/2022/1132.
This document has been produced in the context of the Copernicus Atmosphere Monitoring Service (CAMS). The activities leading to these results have been contracted by the European Centre for Medium-Range Weather Forecasts, operator of CAMS on behalf of the European Union (Delegation Agreement signed on 11/11/2014 and Contribution Agreement signed on 22/07/2021). All information in this document is provided "as is" and no guarantee or warranty is given that the information is fit for any particular purpose. The users thereof use the information at their sole risk and liability. For the avoidance of all doubt , the European Commission and the European Centre for Medium - Range Weather Forecasts have no liability in respect of this document, which is merely representing the author's view. |