The APOLLO cloud product statistics Web service Introduction DLR and Transvalor are preparing a new Web service to disseminate the statistics of the APOLLO cloud physical parameters as a further help in the characterization of a solar site. This Web service preparation phase is done with the help of a grant from ESA 1. A very important part of our work is to assess this future Web service in order to respond as much as possible to the requirements expressed by the renewable energy services and users. This document presents the APOLLO cloud physical parameters computations and the different statistics based on this computation which will be exposed to the user by the Web service. Based on this description, we invite all the interested potential users to fill in and send us back the very short questionnaire send in conjunction with the present document. The APOLLO methodology at a glance The APOLLO methodology uses multiple spectral channels of the METEOSAT Second Generation satellite (MSG) to discriminate between different cloud types. Below is presented picture of water/mixed phase clouds on the left image and thin ice clouds on the right image, as seen from the ground. 1 contract 4000107680/13/I-AM; Expansion of the market for EO Based Information Services in waste management, renewable energy and ecosystem services assessment May 2013 rev. Feb. 2014 1
Karlsruher Wolkenatlas, copyright B. Mühr The APOLLO methodology delivers cloud mask, cloud classification, cloud optical depth, liquid and ice water path, and cloud top temperature and infrared emissivity as cloud parameter products for each MSG SEVIRI pixel in a temporal resolution of 15 minutes during daytime, for the period 2004-2012 (8 years). The covered zone is [60 N,60 S,60 E,60W], with a resolution of 3x3 km2 at the nadir of the satellite [0, 0 ]. This resolution is about 4x5 km2 to 5x6 km2 in Europe. The following parameters are computed and stored: Cloud mask and snow Cloud coverage (0-100%) Cloud type (low, medium, high water/mixed phase clouds; thin ice clouds) Cloud optical depth Cloud top temperature Additionally, a cloud classification scheme delivers information on: vertically extended cold, very thick cloud-layers thin clouds warm and thick water clouds multi-layer clouds stratiform clouds Main statistics delivered by the Apollo WEB service and their possible use for a solar plant sitting or conduct Cloud mask This very basic statistic shows that in the Ulm (Germany) location pixel considered, for the year 2010, about 22% of the time slots were clear, 77% cloudy and 1% with snow on the ground while there is no cloud. Cases with snow on the ground typically represent cases where also photovoltaic panels might be covered with snow resulting in a low yield while the global irradiance is high as it is a cloudfree situation. Cloud mask % of all cases Clear 22 Snow on the ground, no cloud 1 Cloudy 77 May 2013 rev. Feb. 2014 2
Cloud type The cloud type can also be represented as a global number distribution for all the time slots or as a 2D histogram showing the changes in cloud type as a function of the hour of the day. In Ulm, 35% of the day time, there are medium water clouds. The 2D histogram shows also that the medium water clouds are predominant. It shows also that the clear sky periods, were the irradiation will be at its maximum, are at the beginning of the morning or at the end of the day. In case of a location being affected by frequent fog situations, the low water clouds will have a maximum in the early morning hours, as found here for Ulm. Cloud type % of all cases Clear 22 Low height water clouds 11 Medium height water clouds 35 High water clouds 12 High thin ice clouds 20 Cloud overcast type With the computed APOLLO data at the pixel location of interest, it is possible to classify the cloud overcast type and use it for instance to optimize a PV (Photo Voltaic) panel tilt angle or to give additional information for DNI dependant solar installations. Armstrong et al. shows that the optimum tilt angle (OTA) is a function of latitude in cloud free regions of the sun belt with dominating DNI and that in regions where the diffuse part dominates (> 45 N) the OTA is smaller. OTA becomes a function of latitude, frequency of clouds and their type. With a classification into: clear, bright overcast, dark overcast and partly cloudy. May 2013 rev. Feb. 2014 3
clear (1) = at least 90% cloud free pixels; a clear pixel is defined as having max 10% cloud coverage. bright overcast (2) = more than 50% of cloudy pixels, but at least 20% of them are thin ice clouds only dark overcast (3) = more than 50% of cloudy pixels, but more than 80% of them are not thin ice clouds partly cloudy (4) = the rest For Cologne (Germany) and Almeria (Spain), the statistics are shown in the table below. Cologne has generally less clear time slots, and those being cloudy are typically of the dark overcast class. For Almeria, the difference between bright and dark overcast situation occurrence is much less instead of dark overcast situations the number of clear situations is much higher. Both sites show a comparable number of partly cloudy skys. Cloud type Cologne - % of all cases Almeria - % of all cases Clear 12 34 Bright overcast 11 7 Dark overcast 30 13 Partly cloudy 47 46 In Cologne, the dark and bright overcast situations where the diffuse component of the irradiation is predominant represent 41% of the cases. The OTA for PV panels will thus be relatively small in the Germany location. In Almeria, where there are CSP (Concentrated Solar Power) plants relying on DNI, one can also verify that - besides frequent clear sky conditions - there are only 8% of situations of bright overcast (high thin ice clouds). This is a typical situation with a sharp decrease of the DNI due to the scattering of the direct irradiation (and the increase of apparent the sun disk angle), even though there is no significant decrease of the GHI. Cloud scatteredness The analysis is extended further in a 49x49 pixel window around the location of interest. In this window, several values are computed, mostly the number of cloud elements and the cloud shape complexity from the fractal box counting dimension. This fractal box counting dimension represent the complexity of the clouds shape and evolves from zero (a point) through one (a line) to two (an area). In most cases, it lies between one and two if the cloudy pixels clusters in the window are several pixels wide. Specific combinations of these two parameters can be used to define a cloud compactness indicator and are summarized in the following table: Fractal box dimension Nb of cloud elements Cloud compactness indicator 2 1 Overcast 1.7 to 1.9 <=5 Few large clouds 1.8 to 2 >5 Broken clouds 0 to 1.7 <=5 Isolated clouds 0.5 to 1.8 >5 Scattered clouds May 2013 rev. Feb. 2014 4
With these elements, a 2D histogram (for the cloudy time slots only) is plotted which gives a global information on the aspect of the cloud cover at the location when clouds are present in the zone. Below are two examples of the results, the first one for Cologne (Germany) and the second one for Almeria (Spain). In Cologne, the cloudy days are mostly overcast (the dark red spot on the top left corner of the plot) or with a few large clouds or broken clouds. The scattered clouds zone is very small with only a few occurencies (grey color). In Almeria, the scattered clouds or isolated clouds skies are more frequent the scattered clouds zone is populated much more. In case of scattered cloud cases the number of small clouds can reach much higher values than in Cologne. For the scattered cloud cases, the consequences on the PV or CSP systems can be multiple: Overshooting of global irradiance o ramps in irradiance within seconds o power converter outside optimum efficiency range o reduction of system lifetime Rapid changes in direct irradiance o non-linear effects in heat transfer fluids Power output of distributed PV generation o change of average PV production on transformer level o ramps of PV generation cause difficulties in the electricity grid o how many shaded photovoltaic systems do we expect in an area in the next hour? Ramps A ramp is a change from cloudy to clear and vice versa in the cloud mask at the pixel location, from one time slot to the next. The number of ramps per days is an important parameter for the system definition. It can reduce the performance of a CSP system or necessitate a short term electricity storage system even for a PV plant to ensure the stability of the electricity output and the safety of the inverters. The figure below shows the distribution of the number of ramps per day in 2005 for Cologne (Germany - 1283 ramps in total for the year) and Almeria (Spain 1081 ramps in total for the year). In Cologne, only 10% of the days have no ramps at all versus 33% of the days in Almeria. May 2013 rev. Feb. 2014 5
Description of the planned Web service and request for feedback The service is intended to be accessible through the SoDa web site or as an offline request for a given site. The initial result of a query on a location will be a compilation document (.pdf) with all the major statistics results for that location. The availability of the data will increase from a few test points (Version 0) at the very beginning up to a full MSG disk 1 resolution grid for the first version of the product (Version 1). Initially, in the testing phase, we are looking for interested potential users for a testing/feedback phase. This feedback is very important to deliver the most valuable results for the users. Via the short questionnaire joined to this document, we expect to receive first a generic feedback from all potentially interested users on the interest and the results delivered by the WEB service: Do you understand the statistical results delivered by the service? Would you request further statistics based on the APOLLO cloud physical parameters? Do you see a potential use of this statistics in your assessment of a new site sitting or the management of an existing site? Do you think you would/could use such a service (and how often)? Would you be prepared to pay (and maybe how much?) for: o A yearly subscription for the whole MSG covered zone via the SoDa web site o A statistic for a single location from time to time as an offline service In a second phase, in a few months from now, we will offer to an extended panel of interested customers to choose one or a few test sites and deliver to them these statistics. We want to validate the use of these statistics through the comparison against the experience of the customer at the site location (ground measured irradiance, electrical output, cloud observations or weather patterns, etc ). May 2013 rev. Feb. 2014 6