From e0627e64ef955dbe4e8ee0d9248efe9e8ba71e05 Mon Sep 17 00:00:00 2001 From: Bewa Date: Tue, 30 Jul 2024 14:18:15 +0300 Subject: [PATCH] Add files via upload --- Chapter_9_Gridded_Data.qmd | 1450 ++++++++++++++++++------------------ 1 file changed, 722 insertions(+), 728 deletions(-) diff --git a/Chapter_9_Gridded_Data.qmd b/Chapter_9_Gridded_Data.qmd index 546969e..8386fcd 100644 --- a/Chapter_9_Gridded_Data.qmd +++ b/Chapter_9_Gridded_Data.qmd @@ -1,729 +1,723 @@ -# Gridded Data -## Introduction - -There are various sources of gridded data for climatic elements. Those -considered here are from the European Organisation for the Exploitation -of Meteorological Satellites, Satellite Application Facility on Climate -Monitoring (EUMETSAT CM SAF), the Copernicus Climate Change Service -(C3S) Climate Data Store and the International Research Institute for -Climate and Society (IRI) Data Store. - -All data are freely available. You need to register to access data from -CM SAF, and also for the C3S Climate Data Store. The IRI Data Store does -not require registration. The CM SAF data considered here are from -stationary satellites and are available for all of Europe and Africa and -possibly more, e.g. Middle East and Caribbean. Sunshine and radiation -data are illustrated here. They are available daily (some hourly) on a -grid of about 4km and are from 1983. Other elements, e.g. ground -temperature are available hourly, from the early 1990s. They will later -become available from the 1980s. - -We consider the ERA5 reanalysis data from the C3S Climate Data Store. -ERA5 is global, from 1979 (soon to be 1950) with a large number of -elements available hourly on a grid of 0.25 by 0.25 degrees (about -30km). It is illustrated with precipitation (hourly) and with 2m -temperature (used to derive daily Tmax and Tmin). - -The IRI Data Store is a repository of climate data from a wide variety -of sources. We illustrate the IRI Data Store by accessing daily -precipitation estimates from CHIRPS and ENSO and sea-surface -temperatures, that are commonly used for seasonal forecasting. - -There are many possible uses and applications of these data. [To be -continued -- with examples of what can be done and is being -done.]{.mark} - -## Importing NetCDF files - -Show how to use the dialog first without changing options but still look -at details to check what is being imported. - -Then show the options for sub-areas, an individual station, or for -multiple stations. Can use Rwanda station locations and CHIRPS data from -IRI section. - -## EUMETSAT CM SAF - -The CM SAF website is shown in Fig. 9.2a. You are invited to sign-in or -register, though you are welcome to explore what is available without -this. You need to register to download any data. You are then able to -use these data freely. EUMETSAT would very much welcome any feedback on -how the data have been used, particularly if, for example, you have -compared your station data with their data. They may sometimes be -prepared to assist you with using the data. You can contact EUMETSAT -through their User Help Desk -[[https://www.cmsaf.eu/EN/Service/UHD/UHD_node.html]{.underline}](https://www.cmsaf.eu/EN/Service/UHD/UHD_node.html). - - ----------------------------------------------------------------------- - ***Fig. 9.2a*** - ----------------------------------------------------------------------- - ![](media/image234.png){width="6.268055555555556in" - height="2.9381944444444446in"} - - ----------------------------------------------------------------------- - -Choose Surface Radiation products from the Climate Data Records menu in -Fig. 9.2a. Choose daily sunshine duration, SDU, Fig. 9.2b. - -From Fig. 9.2c we see the data are available from 1 January 1983 to the -end of December 2017 (when this guide was written). There are other -products from EUMETSAT CM SAF if more recent data are required, but they -have not been through the homogenisation and quality control checks. - - ----------------------------------------------------------------------------------------------------------- - ***Fig 9.2b*** ***Fig. 9.2c*** - ----------------------------------------------------- ----------------------------------------------------- - ![](media/image235.png){width="3.133465660542432in" ![](media/image220.png){width="2.911786964129484in" - height="2.4349464129483813in"} height="2.7217924321959757in"} - - ----------------------------------------------------------------------------------------------------------- - -Also indicated in Fig. 9.2c is that there is documentation on each -product. Consider downloading these guides if you decide to use the data -as they are very detailed and informative. - -On the same screen as Fig. 9.2c you see an ***Add to Order Cart*** -invitation. Ignore this for now, unless you want a huge file, with data -from about half the globe. - -Instead, scroll further down and click on the button that says ***Change -Projection / spatial resolution / domain***. - - ------------------------------------------------------------------------------------------------------------- - ***Fig. 9.2d*** ***Fig. 9.2e*** - ------------------------------------------------------ ------------------------------------------------------ - ![](media/image242.png){width="2.1938396762904637in" ![](media/image227.png){width="3.9405238407699037in" - height="2.021411854768154in"} height="1.5502766841644795in"} - - ------------------------------------------------------------------------------------------------------------- - -If you are following this as an exercise, then change the coordinates in -Fig. 9.2e. - -Click, in Fig. 9.2e to proceed to the time range selection. - - ------------------------------------------------------------------------------------------------------------- - ***Fig. 9.2f*** ***Fig. 9.2g*** - ------------------------------------------------------ ------------------------------------------------------ - ![](media/image244.png){width="3.1262707786526684in" ![](media/image247.png){width="2.9971336395450567in" - height="2.611187664041995in"} height="1.376020341207349in"} - - ------------------------------------------------------------------------------------------------------------- - -In the following screen, scroll down to confirm that the sub-domain, -part of Rwanda, has been included, Fig. 9.2f. Then press Add to Order -Cart, Fig. 9.2g. - -You return to the screen in Fig. 9.2h. It is disconcerting that in Fig. -9.2h it appears you are about to order a file of over 200 gigabytes, but -it is the size ignoring the sub-domain[^46]. Keep your nerve and place -the order, Fig. 9.2h. - - ----------------------------------------------------------------------- - ***Fig.9.2h*** - ----------------------------------------------------------------------- - ![](media/image253.png){width="6.152322834645669in" - height="2.709448818897638in"} - - ----------------------------------------------------------------------- - -You receive a confirmatory e-mail that the order has been placed on the -EUMETSAT server. Shortly afterwards there is confirmation that the data -have been extracted and are waiting to be downloaded, Fig. 9.2i - - ----------------------------------------------------------------------- - ***Fig. 9.2i*** - ----------------------------------------------------------------------- - ![](media/image249.png){width="6.101929133858268in" - height="2.9671358267716537in"} - - ----------------------------------------------------------------------- - -Follow the instructions in your equivalent of the message in Fig. 9.2i -to download the file. It is now, for the first time that you are made -aware of the file size, 341 Mbytes for this example. - -This downloads a single tar file, containing 12 thousand individual -NetCDF files, with one file for each day. - -This is continued, in Section 9.5, through the CM SAF toolbox and in -Section [xxx]{.mark} using R-Instat. - -## C3S Climate Data Store - -If you are not online, then the first part of this section is again for -reading only. - -The website is . This takes you to -the screen partly shown in Fig. 9.3a. You are invited to login or -register your account. So, do this. - -Once logged in you return to the screen in Fig. 9.3a. - - ----------------------------------------------------------------------- - ***Fig. 9.3a*** - ----------------------------------------------------------------------- - ![](media/image254.png){width="6.124782370953631in" - height="2.761784776902887in"} - - ----------------------------------------------------------------------- - -Then click on Datasets in Fig. 9.3a to give the screen starting in Fig. -9.3b. There are many different datasets available. In the search bar -type "ERA5 hourly" and from the results select, "ERA5 hourly data on -single levels". - -Click on this dataset to get further information, see Fig. 9.3c. - - ------------------------------------------------------------------------------------------------------------ - ***Fig. 9.3b*** ***Fig. 9.3c*** - ----------------------------------------------------- ------------------------------------------------------ - ![](media/image252.png){width="3.026570428696413in" ![](media/image251.png){width="3.0448775153105863in" - height="1.5810192475940508in"} height="2.0040441819772528in"} - - ------------------------------------------------------------------------------------------------------------ - -The data are currently from 1979 (soon to be from 1950). They are -available for many elements including precipitation, temperature, -evaporation, radiation and wind speed and direction. - -They are hourly data and at a 0.25 by 0.25-degree (about 25km) -resolution. - - ------------------------------------------------------------------------------------------------------------ - ***Fig. 9.3d*** ***Fig. 9.3e*** - ----------------------------------------------------- ------------------------------------------------------ - ![](media/image248.png){width="3.128680008748906in" ![](media/image243.png){width="2.8662554680664916in" - height="2.0612062554680666in"} height="2.2056594488188974in"} - - ------------------------------------------------------------------------------------------------------------ - -On your first visit to the site, continue, and click on ***Download -data*** in Fig. 9.3c. You then choose one or more elements, Fig. 9.3d -and decide on the years, months, days and hours to include. Finally, -select the sub-region to extract in the Geographical area section, Fig. -9.3f. Once the items in Fig. 9.3d, Fig. 9.3e and Fig. 9.3f are complete -you can click ***Submit Form*** to start the request. - -The running may take minutes (sometimes many) to complete. It also -sometimes fails. You can view the current status of your requests by -clicking ***Your requests*** from the menu bar shown in Fig. 9.3a. -Occasionally there is a single error 500, in which case just run again. -The other common error is that you have asked for too much data. If you -are requesting a complete time series i.e. for all hours, days, and -months, then the current limit appears to be approximately 5 years. This -limit seems to be the same, irrespective of the area. Hence, for 30 -years, make 6 separate requests, changing the years for each run. You do -not need to wait for a request to complete before starting another one. -Go to ***Your requests*** to see the status of each and download the -data once complete. - - ------------------------------------------------------------------------------------------------------------- - ***Fig. 9.3g Generate a toolbox request*** ***Fig. 9.3h Names for each element*** - ------------------------------------------------------ ------------------------------------------------------ - ![](media/image246.png){width="3.0120089676290465in" ![](media/image241.png){width="3.0938626421697286in" - height="2.827140201224847in"} height="1.705543525809274in"} - - ------------------------------------------------------------------------------------------------------------- - -An alternative way to request data is through the Toolbox, shown in the -menu bar of the homepage in Fig. 9.3a. Previously, it was not possible -to select a sub-region through the interface described above, hence it -was necessary to construct a Python script to run the Toolbox in order -to do this. However, now that sub-region extraction is possible in the -interface, we suggest it is sufficient to use the interface if your main -interest is to download data for use in another software e.g. R or -R-Instat. - -An example Toolbox script to download hourly 2-metre temperature data -for sub-region covering in Rwanda for 5 years in shown Fig. 9.3i. The -Toolbox also includes functionality for processing, analysing and -displaying data, however this is not covered here as we will demonstrate -importing ERA5 data into R-Instat. - -+-----------------------------------------------------------------------+ -| ***Fig. 9.3i Sample toolbox code*** | -+=======================================================================+ -| **import cdstoolbox as ct** | -| | -| **\@ct.application(title=\'Retrieve Data\')** | -| | -| **\@ct.output.dataarray()** | -| | -| **def retrieve_sample_data():** | -| | -| **\"\"\"** | -| | -| **Application main steps:** | -| | -| **- retrieve 2m temperature of ERA5 from CDS Catalogue** | -| | -| **- specify the grid - year(s) - month(s) - day(s) - hour(s)** | -| | -| **- area is optional give N/W/S/E corners** | -| | -| **- recommended for local analysis** | -| | -| **- ask for netcdf format** | -| | -| **\"\"\"** | -| | -| **data = ct.catalogue.retrieve(** | -| | -| **\'reanalysis-era5-single-levels\',** | -| | -| **{** | -| | -| **\'variable\': \'2m_temperature\',** | -| | -| **\'grid\': \[\'0.25\', \'0.25\'\],** | -| | -| **\'product_type\': \'reanalysis\',** | -| | -| **\'year\': \[** | -| | -| **\'1981\','1982','1983','1984','1985'** | -| | -| **\],** | -| | -| **\'month\': \[** | -| | -| **\'01\', \'02\', \'03\', \'04\', \'05\', \'06\',\'07\', \'08\', | -| \'09\', \'10\', \'11\', \'12\',** | -| | -| **\],** | -| | -| **\'day\': \[** | -| | -| **\'01\', \'02\', \'03\', \'04\', \'05\', \'06\',\'07\', \'08\', | -| \'09\', \'10\', \'11\', \'12\',** | -| | -| **\'13\', \'14\', \'15\', \'16\', \'17\', \'18\',\'19\', \'20\', | -| \'21\', \'22\', \'23\', \'24\',** | -| | -| **\'25\', \'26\', \'27\', \'28\', \'29\', \'30\',\'31\'** | -| | -| **\],** | -| | -| **\'time\': \[** | -| | -| **\'00:00\',\'01:00\',\'02:00\',\'03:00\',\'04:00\',\'05:00\',** | -| | -| **\'06:00\',\'07:00\',\'08:00\',\'09:00\',\'10:00\',\'11:00\',** | -| | -| **\'12:00\',\'13:00\',\'14:00\',\'15:00\',\'16:00\',\'17:00\',** | -| | -| **\'18:00\',\'19:00\',\'20:00\',\'21:00\',\'22:00\',\'23:00\'** | -| | -| **\],** | -| | -| **\'area\': \[\'-1.5/30/-2.0/30.54\'\],** | -| | -| **\'format\' : \[\'netcdf\'\]** | -| | -| **})** | -| | -| **return data** | -+-----------------------------------------------------------------------+ - -The second stage is to read the resulting data into R-Instat. For those -who were not online, the six files have also been renamed and copied -into the R-Instat library. - -***Go into R-Instat*** and use ***File \> Open and Tidy NetCDF File*** -Fig. 9.3j. - - ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------- - ***Fig. 9.3j Loading the data for 1981-5*** ***Fig. 9.3k Six files in R-Instat*** - ---------------------------------------------------------------------------------------------------------------------- ----------------------------------------------------- - ![C:\\Users\\ROGERS\~1\\AppData\\Local\\Temp\\SNAGHTML145541b7.PNG](media/image191.png){width="3.2002351268591425in" ![](media/image197.png){width="2.920479002624672in" - height="1.9078324584426947in"} height="2.9872025371828523in"} - - ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------- - -In Fig. 9.3j, if you downloaded your own data, then choose ***Browse***, -otherwise choose ***From Library*** and ***use the file called -cds.Rwanda_1981_5.nc***. - -Then recall the last dialogue and include the other five files, up to -cds.Rwanda_2005_10. The resulting data are shown in Fig. 9.3k. There are -about 394,416 rows of data in each file (i.e. roughly 9 \* 24 \* 365 \* -5) - -The next step is to append the files to give the 30-year record. Use -***Climatic \>Tidy and Examine \> Append***, Fig. 9.3l. In Fig. 9.3l, -include all 6 data frame, then the ID column isn't needed and the -resulting data frame is named better than Append1. - - ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------- - ***Fig. 9.3l Appending the 6 data frames*** ***Fig. 9.3m Temperatures into centigrade*** - --------------------------------------------------------------------------------------------------------------------- ------------------------------------------------------ - ![C:\\Users\\ROGERS\~1\\AppData\\Local\\Temp\\SNAGHTML14701350.PNG](media/image203.png){width="3.084857830271216in" ![](media/image196.png){width="2.7211132983377078in" - height="2.3588156167979in"} height="3.437498906386702in"} - - ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------- - -The data column in Fig. 9.3k, called tas, is in degrees Kelvin. Use -***Climatic \> Prepare \> Transform*** to change them into centigrade -for comparison with the station data, Fig. 9.3m. - -ECMWF provides the time variable always in GMT (Greenwich Mean Time). -Rwanda is 2 hours ahead, so either, or both, the time variables in Fig. -9.3k need to be moved forward by 2 hours. To make this change the data -should first be in "station" order. Hence first ***Right-Click*** and -choose ***Sort*** (or use Prepare \> Data Frame \> Sort) to produce the -dialogue in Fig. 9.3n. - -Now use ***Prepare \> Column: Calculate \> Calculations*** as shown in -Fig. 9.3o. In the calculator the ***Transform*** keyboard includes the -***lead*** function. The function, from the dplyr package is: - -***dplyr::lead(time_full,2)***, to move to Rwanda time. Pressing the -***Try*** button in Fig. 9.3o shows the first value is now 2am GMT[^47]. - - ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------- - ***Fig. 9.3n*** ***Fig. 9.3o*** - ---------------------------------------------------------------------------------------------------------------------- ----------------------------------------------------- - ![C:\\Users\\ROGERS\~1\\AppData\\Local\\Temp\\SNAGHTML14c5504c.PNG](media/image199.png){width="3.1133234908136482in" ![](media/image198.png){width="2.914620516185477in" - height="3.026656824146982in"} height="3.134375546806649in"} - - ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------- - -Now use ***Climatic \> Dates \> Make Date*** to make a new Date column -from the Rwanda hourly column, Fig. 9.3p. - - ------------------------------------------------------------------------------------------------------------- - ***Fig. 9.3p*** ***Fig. 9.3q*** - ------------------------------------------------------ ------------------------------------------------------ - ![](media/image200.png){width="2.9332370953630797in" ![](media/image195.png){width="3.1684503499562555in" - height="2.824397419072616in"} height="2.5948917322834646in"} - - ------------------------------------------------------------------------------------------------------------- - -Finally generate Tmax and Tmin, on a daily basis, from the hourly -values, ready to use, or to compare with station data. First -***right-click*** and make the ***lon and lat columns into factors***. -The hourly data are now roughly as in Fig. 9.3q - -Complete the ***Prepare \> Column: Reshape \> Column Summaries*** -dialogue as shown in Fig. 9.3r. As these are temperatures the daily -maximum and minimum are calculated. The resulting worksheet, Fig. 9.3s, -has a more reasonable 100,000 rows of data at the 9 gridpoints. - -+------------------------------------+---------------------------------+ -| ***Fig. 9.3r*** | ***Fig. 9.3s Resulting daily | -| | data*** | -| ***Prepare \> Column: Reshape \> | | -| Column Summaries*** | | -| | | -| ***(Make max and min the | | -| summaries)*** | | -+====================================+=================================+ -| ![](media/image184 | ![](media/image186.pn | -| .png){width="3.1482884951881016in" | g){width="2.9195363079615047in" | -| height="3.011654636920385in"} | height="2.777613735783027in"} | -+------------------------------------+---------------------------------+ - -## The IRI Data Store - -A third source of gridded data considered here is the IRI Data Library. -IRI is the International Research Institute for Climate and Society -based in Colombia University, USA. The website for their data library is -[[http://iridl.ldeo.columbia.edu/]{.underline}](http://iridl.ldeo.columbia.edu/) -, Fig. 9.4a. The IRI Data Store is a large repository of climate data -from a wide variety of sources. In many cases, the IRI Data Store is not -the only, or primary, source of the data, however the IRI Data Store -provides a simple consistent way of freely downloading from a large set -of sources, and crucially allows for selecting sub-regions. - -As well as downloading from the website, R-Instat includes a dialog to -directly download and import some of the common data from the IRI Data -Store. We demonstrate both methods here, using the R-Instat dialog to -download CHIRPS daily rainfall estimates and the IRI Data Store website -to download information on ENSO and sea surface temperatures. - -### Downloading directly from R-Instat - -Climate Hazards Group InfraRed Precipitation with Station data (CHIRPS), -produced by Climate Hazards Center UC Santa Barbara, USA, is a -near-global gridded rainfall data set, available from 1981 to -near-present with a spatial resolution of 0.05°. It is constructed by -combining satellite imagery and in-situ station data, and is available -on a daily, dekad and monthly basis. It's website is here -[[https://www.chc.ucsb.edu/data/chirps]{.underline}](https://www.chc.ucsb.edu/data/chirps) -but the data is more easily available to download and subset from the -IRI Data Store. It is an example of one of the datasets available to -download directly from R-Instat. - -In R-Instat go to ***Climatic \> File \> Import from IRI Data -Library***, fig xxx. First select "UCSB CHIRPS" as the ***Source***. We -will download the daily data with the highest resolution available, -hence choose "Daily Precipitation 0.05 degree" as the ***Data***, fig -xxx. Source shows a limited set of data sources available in the IRI -Data Store which we think will be most commonly used by R-Instat users. -If there is a dataset from the IRI Data Store that you commonly use and -think we should add, please let us know and we can consider adding it to -the dialog. - -The next two sections of the dialog allow for choosing a subset of time -or location. By default, "Entire Range" is selected for the data range. -For CHIRPS, this means 1981 to near-present. We will use this option, -but if you want a shorter time period choose "Custom Range" and select -the "From" and "To" dates. The Location Range allows you to choose an -area defined by longitude and latitude limits, or a single point, which -will extract the nearest grid point to the location you provide. Let's -first choose a single point for Kigali, Rwanda at longitude 30.1 and -latitude -1.95, fig xxx. - -The dialog will connect to the IRI Data Library and download the -requested data to your machine as a NetCDF file (.nc), a common format -for gridded data (CM SAF and C3S Climate Data Store data are also -provided in this format). Click ***Browse*** to choose where the -download data will be saved to or accept the default of your Documents -folder. Choose an appropriate name for the new data frame. Now, click -***Ok*** to download and import the data into R-Instat. It may take some -time for the request to be processed (up to 30 minutes), particularly -for requests that are for a long time period since data are usually -stored in separate files for each time point. However, this does not -mean the download will be a large file and the time can vary depending -on how busy the IRI Data Library servers are. While waiting, you will -see the R-Instat waiting dialog and the download progress bar. Do not -worry if the progress bar does not move forward, this just means the -request is still being processed. Once the request has been processed, -the download will usually be small and take very little time. For -example, this request should result in a download file of size \~0.1MB. - -After finishing you will see the data imported into R-Instat, fig xxx. -The NetCDF file has been downloaded to the location chosen on the dialog -(Documents by default) and the file has been imported into a data frame -in R-Instat. The data frame has five columns. X and Y are the location -and this should be constant since we requested a single point. Notice -that the value in Y is not exactly what we request. It is -1.97 and we -request -1.95. This is because the closed grid point in the CHIRPS data -grid to the provided location is selected. .T is time as a number and -T_date is a more useful column that is created by R-Instat when -importing as a Date column. prcp is precipitation. We can confirm this -by looking at the column metadata: ***View \> Column Metadata***. Scroll -to the end to see the "standard_name" and "units" columns which confirm -what each column represents and its units, fig xxx. Click ***View \> -Column Metadata*** again to close the metadata. We can see that each row -in the data represents a single day, starting on 1981-01-01. Use -***Describe \> One Variable \> Summaries***, and select all columns to -see a summary of the data. The output is shown in fig xxx. We see that X -and Y are constant, as expected. .T is numeric and not that useful, but -T_date show the data ranges from 1981-01-01 to 2020-08-31 (as of October -2020, usually 1 or 2 months behind the current date). prcp shows a -sensible set of summaries for daily rainfall values. This is useful to -do to confirm that the request is as you expected. For example, if X and -Y are not constant but you wanted just a single point, then you may not -have done the request correctly. - -Notice that the data file is also stored on your machine in the folder -you chose. For example, in Documents my file is called -ucsb_chirps7f14482329.nc. If you need to import this data again, you can -now use the file directly, without requesting it again from the IRI Data -Store. See section xxx on how to import NetCDF files. - -This data is useful for comparison with a single station in Kigali. We -often have data from multiple stations and would wish to extract gridded -data at each of the station locations. One way to do this would be to -make separate requests for each station location using the Import from -IRI Data Library multiple times. However, this becomes time consuming -for many stations, particularly if the processing time is slow. Another -option is to do a single request and download data for an area that -covers all the station locations and then afterwards extract the data -for the required locations. - -So let's to this by download the same data for an area that covers -Rwanda instead of a single point. This will be a larger download file -\~280MB but should not take much longer to process. If you have an -internet connection able to download \~300MB of data then try the next -steps below. If not, then this is just for reading. - -Go back to the ***Import from IRI Data Library*** dialog. The -***Source***, ***Data*** and ***Date Range*** options remain the same. -Change the ***Location Range*** option from "Point" to "Area" and enter -the values: longitude: min 28.5, max 30.5, latitude: min -2.5, max -1.4. -This area covers the four stations in Rwanda found in the R-Instat -Library. Choose the location to save the download or use the same -location. Now, the data request is for approximately a 2 degrees by 1 -degree area, which will give approximately (2 / 0.05) x (1 / 0.05) = 40 -x 20 = 800 grid points, since the resolution is 0.05 degrees. We do not -want to directly import all 800 grid points into R-Instat as this would -be equivalent to 800 station records for 40 years. Instead, we want to -download the data and then extract only a few grid points of interest -afterwards. So we will check the option for "Don't import data after -downloading". This removes the new data frame name as it will not import -into R-Instat but will just download to your machine. Now click ***Ok*** -and it may take a similar amount of time to complete. - -After finishing you will not see any change in R-Instat but the file -will be downloaded to the chosen folder. We can now use the dialog at -***Climatic \> File \> Import & Tidy NetCDF*** to import a subset of the -grid points based on station locations. This is shown in section xxx. - -### Download from the IRI Data Store - -As examples, information on ENSO and sea surface temperatures are -accessed. The maproom also contains instructional information, so typing -ENSO into the search, Fig. 9.4a, provides useful information, including -the areas of the Pacific ocean associated with the NINO situations, Fig. -9.4b. Fig. 9.4b is accessed directly from -[[https://iridl.ldeo.columbia.edu/maproom/ENSO/Diagnostics.html]{.underline}](https://iridl.ldeo.columbia.edu/maproom/ENSO/Diagnostics.html) - - ------------------------------------------------------------------------------------------------------------ - ***Fig.9.4a IRI Data Library*** ***Fig. 9.4b NINO3.4*** - ------------------------------------------------------ ----------------------------------------------------- - ![](media/image211.png){width="3.8668733595800524in" ![](media/image221.png){width="2.130990813648294in" - height="2.70544072615923in"} height="2.7068285214348204in"} - - ------------------------------------------------------------------------------------------------------------ - -In Fig. 9.4a click on Data by Category, then on Climate Indices, Fig. -9.4c and choose Indices nino EXTENDED, Fig. 9.4d. - - ------------------------------------------------------------------------------------------------------------- - ***Fig. 9.4c*** - ------------------------------------------------------ ------------------------------------------------------ - ![](media/image229.png){width="2.6998807961504814in" ![](media/image228.png){width="3.4260433070866143in" - height="2.4705489938757657in"} height="2.2284437882764654in"} - - ------------------------------------------------------------------------------------------------------------- - -Choose ***nino34***, in Fig. 9.4e and then go straight to ***data -files***. The next screen shows a variety of output formats, including -NetCDF, which you choose. - - ----------------------------------------------------------------------------------------------------------- - ***Fig. 9.4e*** ***Fig. 9.4f*** - ----------------------------------------------------- ----------------------------------------------------- - ![](media/image223.png){width="3.075055774278215in" ![](media/image201.png){width="2.899403980752406in" - height="3.0795778652668417in"} height="3.59878280839895in"} - - ----------------------------------------------------------------------------------------------------------- - -Now, in R-Instat, use File \> Open and Tidy NetCDF File. If you followed -the screens above, then browse for the file that was downloaded. -Otherwise there is a copy in the R-Instat library to March 2019, Fig. -9.4g. - - -------------------------------------------------------------------------------------------------------------------------------------------------------------------------- - ***Fig. 9.4g*** ***Fig. 9.4h*** - --------------------------------------------------------------------------------------------------------------------- ---------------------------------------------------- - ![C:\\Users\\ROGERS\~1\\AppData\\Local\\Temp\\SNAGHTMLda15af6.PNG](media/image216.png){width="3.1782567804024495in" ![](media/image222.png){width="2.99167760279965in" - height="1.8947287839020122in"} height="2.0226049868766403in"} - - -------------------------------------------------------------------------------------------------------------------------------------------------------------------------- - -The data are now imported into R-Instat, Fig. 9.4h. The time variable -has not been recognised as a date. You may wish to click on the I (for -information -- the metadata) and this will confirm that the column, -called T, is months since January 1960. If the fact that some values -appear the same in this column, then change the number of significant -figures in that column, from 3 to 5. - -The first value of T, in Fig. 9.4h is -1248. Dividing by 12 gives 104 -years, so the data start in January 1856! - -Use Climatic \> Dates \> Generate Dates, Fig. 9.4i. In Fig. 9.4i, change -the starting date to January 1856, the end date to March 2019 (if using -the library dataset), and the step to 1 Month. The resulting date column -is shown in Fig. 9.4j. - - ------------------------------------------------------------------------------------------------------------ - ***Fig. 9.4i*** ***Fig. 9.4j*** - ----------------------------------------------------- ------------------------------------------------------ - ![](media/image217.png){width="2.841988188976378in" ![](media/image210.png){width="2.6477077865266843in" - height="2.867364391951006in"} height="3.06124343832021in"} - - ------------------------------------------------------------------------------------------------------------ - -Countries have their own definition of when the NINO3.4 implies a year, -or season is El Niño, or La Niña, see -[[https://en.wikipedia.org/wiki/El_Ni%C3%B1o]{.underline}](https://en.wikipedia.org/wiki/El_Ni%C3%B1o), -some use the NINO3.4 value and others use NINo3, or even NINO1 and 2. -The site -[[http://www.bom.gov.au/climate/enso/enlist/index.shtml]{.underline}](http://www.bom.gov.au/climate/enso/enlist/index.shtml) -gives a detailed description of El Niño events since 1900, Fig. 9.4k, -with a companion page for La Niña. - - ------------------------------------------------------------------------------------------------------------ - ***Fig. 9.4k*** ***Fig. 9.4l*** - ----------------------------------------------------- ------------------------------------------------------ - ![](media/image127.png){width="3.470980971128609in" ![](media/image128.png){width="2.5918022747156604in" - height="2.1808070866141733in"} height="1.7213331146106736in"} - - ------------------------------------------------------------------------------------------------------------ - -The SSTs themselves are often used for seasonal forecasting. This is -illustrated with the SSTs for the Nino3.4 region. - -***Return to the main page***, Fig. 9.4a, then choose ***Data by -Category*** again, but this time, in Fig. 9.4c, choose ***Air-Sea -Interface***. In the resulting screen, choose the ***NOAA NCDC ERSST -version5***, Fig. 9.4l. - -In the resulting screen, Fig. 9.4m, choose ***anomalies*** and then -***Data Selection***. - - ------------------------------------------------------------------------------------------------------------ - ***Fig. 9.4m*** ***Fig. 9.4n*** - ----------------------------------------------------- ------------------------------------------------------ - ![](media/image156.png){width="2.991107830271216in" ![](media/image130.png){width="3.0622233158355208in" - height="2.34369750656168in"} height="2.5905457130358704in"} - - ------------------------------------------------------------------------------------------------------------ - -Set the ***time, attitude and longitude*** as shown in Fig. 9.4n and -then ***Restrict Ranges***. The part at the top of Fig. 9.4n should -change accordingly and you now press ***Stop Selecting***. - -Fig. 9.4m now has the three ranges added, in blue, Fig. 9.4o. Click on -Data Files to give the same as Fig. 9.4f, earlier. Choose the NetCDF -option again to download the file. - - ----------------------------------------------------------------------------------------------------------- - ***Fig. 9.4o*** ***Fig. 9.4p*** - ----------------------------------------------------- ----------------------------------------------------- - ![](media/image141.png){width="2.780994094488189in" ![](media/image183.png){width="3.290544619422572in" - height="1.8450831146106736in"} height="2.7998042432195978in"} - - ----------------------------------------------------------------------------------------------------------- - -Use the File \> Input and Tidy NetCDF File as in Fig. 9.4g. Then use the -Climatic \> Dates \> Generate Dates dialogue as shown in Fig. 9.4p. In -Fig. 9.4p, remember to change to the new data frame. Then set the -starting date to January 1921 and there are now 130 values (26 E-W, by 5 -N-S) at each time point. - -In Fig. 9.4p, if all is correct, the generated sequence should match the -length of the data frame. Once accepted, the resulting data frame is -shown in Fig. 9.4q. Here each pixel is a 2 degree square, so the first -row is the temperature anomaly round 120°W and 4°S for January 1921. - - ----------------------------------------------------------------------- - ***Fig. 9.4q*** - ----------------------------------------------------------------------- - ![](media/image102.png){width="2.993989501312336in" - height="3.175609142607174in"} - - ----------------------------------------------------------------------- - -## Using the CM SAF toolbox for NetCDF files - -The CM SAF toolbox is an R software package designed to process the -NetCDF files downloaded from EUMETSAT, Section 9.3. It is used on the -downloaded files from EUMETSAT (or from other organisations who have -NetCDF files). This may be all you need, if your interest is in some -products from the EUMETSAT data. Or it may be before using R-Instat if -your interest is in comparing station and satellite data. - -## Defining ENSO - -See -[[https://www.ncdc.noaa.gov/teleconnections/enso/indicators/sst/]{.underline}](https://www.ncdc.noaa.gov/teleconnections/enso/indicators/sst/) - -[Warm and cold phases are defined as a minimum of five consecutive -3-month running mean of SST anomalies -([[ERSST.v5]{.underline}](http://origin.cpc.ncep.noaa.gov/products/analysis_monitoring/ensostuff/ONI_v5.php)) +# Gridded Data +## Introduction + +There are various sources of gridded data for climatic elements. Those +considered here are from the European Organisation for the Exploitation +of Meteorological Satellites, Satellite Application Facility on Climate +Monitoring (EUMETSAT CM SAF), the Copernicus Climate Change Service +(C3S) Climate Data Store and the International Research Institute for +Climate and Society (IRI) Data Store. + +All data are freely available. You need to register to access data from +CM SAF, and also for the C3S Climate Data Store. The IRI Data Store does +not require registration. The CM SAF data considered here are from +stationary satellites and are available for all of Europe and Africa and +possibly more, e.g. Middle East and Caribbean. Sunshine and radiation +data are illustrated here. They are available daily (some hourly) on a +grid of about 4km and are from 1983. Other elements, e.g. ground +temperature are available hourly, from the early 1990s. They will later +become available from the 1980s. + +We consider the ERA5 reanalysis data from the C3S Climate Data Store. +ERA5 is global, from 1979 (soon to be 1950) with a large number of +elements available hourly on a grid of 0.25 by 0.25 degrees (about +30km). It is illustrated with precipitation (hourly) and with 2m +temperature (used to derive daily Tmax and Tmin). + +The IRI Data Store is a repository of climate data from a wide variety +of sources. We illustrate the IRI Data Store by accessing daily +precipitation estimates from CHIRPS and ENSO and sea-surface +temperatures, that are commonly used for seasonal forecasting. + +There are many possible uses and applications of these data. [To be +continued -- with examples of what can be done and is being +done.]{.mark} + +## Importing NetCDF files + +Show how to use the dialog first without changing options but still look +at details to check what is being imported. + +Then show the options for sub-areas, an individual station, or for +multiple stations. Can use Rwanda station locations and CHIRPS data from +IRI section. + +## EUMETSAT CM SAF + +The CM SAF website is shown in Fig. 9.2a. You are invited to sign-in or +register, though you are welcome to explore what is available without +this. You need to register to download any data. You are then able to +use these data freely. EUMETSAT would very much welcome any feedback on +how the data have been used, particularly if, for example, you have +compared your station data with their data. They may sometimes be +prepared to assist you with using the data. You can contact EUMETSAT +through their User Help Desk +[[https://www.cmsaf.eu/EN/Service/UHD/UHD_node.html]{.underline}](https://www.cmsaf.eu/EN/Service/UHD/UHD_node.html). + + ----------------------------------------------------------------------- + ***Fig. 9.2a*** + ----------------------------------------------------------------------- + ![](figures/Fig9.2a.png){width="6.268055555555556in" + height="2.9381944444444446in"} + + ----------------------------------------------------------------------- + +Choose Surface Radiation products from the Climate Data Records menu in +Fig. 9.2a. Choose daily sunshine duration, SDU, Fig. 9.2b. + +From Fig. 9.2c we see the data are available from 1 January 1983 to the +end of December 2017 (when this guide was written). There are other +products from EUMETSAT CM SAF if more recent data are required, but they +have not been through the homogenisation and quality control checks. + + ----------------------------------------------------------------------------------------------------------- + ***Fig 9.2b*** ***Fig. 9.2c*** + ----------------------------------------------------- ----------------------------------------------------- + ![](figures/Fig9.2b.png){width="3.133465660542432in" ![](figures/Fig9.2c.png){width="2.911786964129484in" + height="2.4349464129483813in"} height="2.7217924321959757in"} + + ----------------------------------------------------------------------------------------------------------- + +Also indicated in Fig. 9.2c is that there is documentation on each +product. Consider downloading these guides if you decide to use the data +as they are very detailed and informative. + +On the same screen as Fig. 9.2c you see an ***Add to Order Cart*** +invitation. Ignore this for now, unless you want a huge file, with data +from about half the globe. + +Instead, scroll further down and click on the button that says ***Change +Projection / spatial resolution / domain***. + + ------------------------------------------------------------------------------------------------------------- + ***Fig. 9.2d*** ***Fig. 9.2e*** + ------------------------------------------------------ ------------------------------------------------------ + ![](figures/Fig9.2d.png){width="2.1938396762904637in" ![](figures/Fig9.2e.png){width="3.9405238407699037in" + height="2.021411854768154in"} height="1.5502766841644795in"} + + ------------------------------------------------------------------------------------------------------------- + +If you are following this as an exercise, then change the coordinates in +Fig. 9.2e. + +Click, in Fig. 9.2e to proceed to the time range selection. + + ------------------------------------------------------------------------------------------------------------- + ***Fig. 9.2f*** ***Fig. 9.2g*** + ------------------------------------------------------ ------------------------------------------------------ + ![](figures/Fig9.2f.png){width="3.1262707786526684in" ![](figures/Fig9.2g.png){width="2.9971336395450567in" + height="2.611187664041995in"} height="1.376020341207349in"} + + ------------------------------------------------------------------------------------------------------------- + +In the following screen, scroll down to confirm that the sub-domain, +part of Rwanda, has been included, Fig. 9.2f. Then press Add to Order +Cart, Fig. 9.2g. + +You return to the screen in Fig. 9.2h. It is disconcerting that in Fig. +9.2h it appears you are about to order a file of over 200 gigabytes, but +it is the size ignoring the sub-domain[^46]. Keep your nerve and place +the order, Fig. 9.2h. + + ----------------------------------------------------------------------- + ***Fig.9.2h*** + ----------------------------------------------------------------------- + ![](figures/Fig9.2h.png){width="6.152322834645669in" + height="2.709448818897638in"} + + ----------------------------------------------------------------------- + +You receive a confirmatory e-mail that the order has been placed on the +EUMETSAT server. Shortly afterwards there is confirmation that the data +have been extracted and are waiting to be downloaded, Fig. 9.2i + + ----------------------------------------------------------------------- + ***Fig. 9.2i*** + ----------------------------------------------------------------------- + ![](figures/Fig9.2i.png){width="6.101929133858268in" + height="2.9671358267716537in"} + + ----------------------------------------------------------------------- + +Follow the instructions in your equivalent of the message in Fig. 9.2i +to download the file. It is now, for the first time that you are made +aware of the file size, 341 Mbytes for this example. + +This downloads a single tar file, containing 12 thousand individual +NetCDF files, with one file for each day. + +This is continued, in Section 9.5, through the CM SAF toolbox and in +Section [xxx]{.mark} using R-Instat. + +## C3S Climate Data Store + +If you are not online, then the first part of this section is again for +reading only. + +The website is . This takes you to +the screen partly shown in Fig. 9.3a. You are invited to login or +register your account. So, do this. + +Once logged in you return to the screen in Fig. 9.3a. + + ----------------------------------------------------------------------- + ***Fig. 9.3a*** + ----------------------------------------------------------------------- + ![](figures/Fig9.3a.png){width="6.124782370953631in" + height="2.761784776902887in"} + + ----------------------------------------------------------------------- + +Then click on Datasets in Fig. 9.3a to give the screen starting in Fig. +9.3b. There are many different datasets available. In the search bar +type "ERA5 hourly" and from the results select, "ERA5 hourly data on +single levels". + +Click on this dataset to get further information, see Fig. 9.3c. + + ------------------------------------------------------------------------------------------------------------ + ***Fig. 9.3b*** ***Fig. 9.3c*** + ----------------------------------------------------- ------------------------------------------------------ + ![](figures/Fig9.3b.png){width="3.026570428696413in" ![](figures/Fig9.3c.png){width="3.0448775153105863in" + height="1.5810192475940508in"} height="2.0040441819772528in"} + + ------------------------------------------------------------------------------------------------------------ + +The data are currently from 1979 (soon to be from 1950). They are +available for many elements including precipitation, temperature, +evaporation, radiation and wind speed and direction. + +They are hourly data and at a 0.25 by 0.25-degree (about 25km) +resolution. + + ------------------------------------------------------------------------------------------------------------ + ***Fig. 9.3d*** ***Fig. 9.3e*** + ----------------------------------------------------- ------------------------------------------------------ + ![](figures/Fig9.3d.png){width="3.128680008748906in" ![](figures/Fig9.3e.png){width="2.8662554680664916in" + height="2.0612062554680666in"} height="2.2056594488188974in"} + + ------------------------------------------------------------------------------------------------------------ + +On your first visit to the site, continue, and click on ***Download +data*** in Fig. 9.3c. You then choose one or more elements, Fig. 9.3d +and decide on the years, months, days and hours to include. Finally, +select the sub-region to extract in the Geographical area section, Fig. +9.3f. Once the items in Fig. 9.3d, Fig. 9.3e and Fig. 9.3f are complete +you can click ***Submit Form*** to start the request. + +The running may take minutes (sometimes many) to complete. It also +sometimes fails. You can view the current status of your requests by +clicking ***Your requests*** from the menu bar shown in Fig. 9.3a. +Occasionally there is a single error 500, in which case just run again. +The other common error is that you have asked for too much data. If you +are requesting a complete time series i.e. for all hours, days, and +months, then the current limit appears to be approximately 5 years. This +limit seems to be the same, irrespective of the area. Hence, for 30 +years, make 6 separate requests, changing the years for each run. You do +not need to wait for a request to complete before starting another one. +Go to ***Your requests*** to see the status of each and download the +data once complete. + + ------------------------------------------------------------------------------------------------------------- + ***Fig. 9.3f Generate a toolbox request*** ***Fig. 9.3g Names for each element*** + ------------------------------------------------------ ------------------------------------------------------ + ![](figures/Fig9.3f.png){width="3.0120089676290465in" ![](figures/Fig9.3g.png){width="3.0938626421697286in" + height="2.827140201224847in"} height="1.705543525809274in"} + + ------------------------------------------------------------------------------------------------------------- + +An alternative way to request data is through the Toolbox, shown in the +menu bar of the homepage in Fig. 9.3a. Previously, it was not possible +to select a sub-region through the interface described above, hence it +was necessary to construct a Python script to run the Toolbox in order +to do this. However, now that sub-region extraction is possible in the +interface, we suggest it is sufficient to use the interface if your main +interest is to download data for use in another software e.g. R or +R-Instat. + +An example Toolbox script to download hourly 2-metre temperature data +for sub-region covering in Rwanda for 5 years in shown Fig. 9.3i. The +Toolbox also includes functionality for processing, analysing and +displaying data, however this is not covered here as we will demonstrate +importing ERA5 data into R-Instat. + ++-----------------------------------------------------------------------+ +| ***Fig. 9.3h Sample toolbox code*** | ++=======================================================================+ +| **import cdstoolbox as ct** | +| | +| **\@ct.application(title=\'Retrieve Data\')** | +| | +| **\@ct.output.dataarray()** | +| | +| **def retrieve_sample_data():** | +| | +| **\"\"\"** | +| | +| **Application main steps:** | +| | +| **- retrieve 2m temperature of ERA5 from CDS Catalogue** | +| | +| **- specify the grid - year(s) - month(s) - day(s) - hour(s)** | +| | +| **- area is optional give N/W/S/E corners** | +| | +| **- recommended for local analysis** | +| | +| **- ask for netcdf format** | +| | +| **\"\"\"** | +| | +| **data = ct.catalogue.retrieve(** | +| | +| **\'reanalysis-era5-single-levels\',** | +| | +| **{** | +| | +| **\'variable\': \'2m_temperature\',** | +| | +| **\'grid\': \[\'0.25\', \'0.25\'\],** | +| | +| **\'product_type\': \'reanalysis\',** | +| | +| **\'year\': \[** | +| | +| **\'1981\','1982','1983','1984','1985'** | +| | +| **\],** | +| | +| **\'month\': \[** | +| | +| **\'01\', \'02\', \'03\', \'04\', \'05\', \'06\',\'07\', \'08\', | +| \'09\', \'10\', \'11\', \'12\',** | +| | +| **\],** | +| | +| **\'day\': \[** | +| | +| **\'01\', \'02\', \'03\', \'04\', \'05\', \'06\',\'07\', \'08\', | +| \'09\', \'10\', \'11\', \'12\',** | +| | +| **\'13\', \'14\', \'15\', \'16\', \'17\', \'18\',\'19\', \'20\', | +| \'21\', \'22\', \'23\', \'24\',** | +| | +| **\'25\', \'26\', \'27\', \'28\', \'29\', \'30\',\'31\'** | +| | +| **\],** | +| | +| **\'time\': \[** | +| | +| **\'00:00\',\'01:00\',\'02:00\',\'03:00\',\'04:00\',\'05:00\',** | +| | +| **\'06:00\',\'07:00\',\'08:00\',\'09:00\',\'10:00\',\'11:00\',** | +| | +| **\'12:00\',\'13:00\',\'14:00\',\'15:00\',\'16:00\',\'17:00\',** | +| | +| **\'18:00\',\'19:00\',\'20:00\',\'21:00\',\'22:00\',\'23:00\'** | +| | +| **\],** | +| | +| **\'area\': \[\'-1.5/30/-2.0/30.54\'\],** | +| | +| **\'format\' : \[\'netcdf\'\]** | +| | +| **})** | +| | +| **return data** | ++-----------------------------------------------------------------------+ + +The second stage is to read the resulting data into R-Instat. For those +who were not online, the six files have also been renamed and copied +into the R-Instat library. + +***Go into R-Instat*** and use ***File \> Open and Tidy NetCDF File*** +Fig. 9.3i. + + ------------------------------------------------------------------------------------------------------------- + ***Fig. 9.3i Loading the data for 1981-5*** ***Fig. 9.3j Six files in R-Instat*** + ------------------------------------------------------ ------------------------------------------------------ + ![](figures/Fig9.3i.png){width="2.9332370953630797in" ![](figures/Fig9.3j.png){width="3.1684503499562555in" + height="2.824397419072616in"} height="2.5948917322834646in"} + + ------------------------------------------------------------------------------------------------------------- + +In Fig. 9.3j, if you downloaded your own data, then choose ***Browse***, +otherwise choose ***From Library*** and ***use the file called +cds.Rwanda_1981_5.nc***. + +Then recall the last dialogue and include the other five files, up to +cds.Rwanda_2005_10. The resulting data are shown in Fig. 9.3k. There are +about 394,416 rows of data in each file (i.e. roughly 9 \* 24 \* 365 \* +5) + +The next step is to append the files to give the 30-year record. Use +***Climatic \>Tidy and Examine \> Append***, Fig. 9.3l. In Fig. 9.3k, +include all 6 data frame, then the ID column isn't needed and the +resulting data frame is named better than Append1. + + ------------------------------------------------------------------------------------------------------------- + ***Fig. 9.3k Appending the 6 data frames*** ***Fig. 9.3l Temperatures into centigrade*** + ------------------------------------------------------ ------------------------------------------------------ + ![](figures/Fig9.3k.png){width="3.1482884951881016in" ![](figures/Fig9.3l.png){width="2.9195363079615047in" + height="3.011654636920385in"} height="2.777613735783027in"} + + ------------------------------------------------------------------------------------------------------------- + +The data column in Fig. 9.3k, called tas, is in degrees Kelvin. Use +***Climatic \> Prepare \> Transform*** to change them into centigrade +for comparison with the station data, Fig. 9.3m. + +ECMWF provides the time variable always in GMT (Greenwich Mean Time). +Rwanda is 2 hours ahead, so either, or both, the time variables in Fig. +9.3k need to be moved forward by 2 hours. To make this change the data +should first be in "station" order. Hence first ***Right-Click*** and +choose ***Sort*** (or use Prepare \> Data Frame \> Sort) to produce the +dialogue in Fig. 9.3m. + +Now use ***Prepare \> Column: Calculate \> Calculations*** as shown in +Fig. 9.3n. In the calculator the ***Transform*** keyboard includes the +***lead*** function. The function, from the dplyr package is: + +***dplyr::lead(time_full,2)***, to move to Rwanda time. Pressing the +***Try*** button in Fig. 9.3n shows the first value is now 2am GMT[^47]. + + ------------------------------------------------------------------------------------------------------------- + ***Fig. 9.3m*** ***Fig. 9.3n*** + ------------------------------------------------------ ------------------------------------------------------ + ![](figures/Fig9.3m.png){width="3.1482884951881016in" ![](figures/Fig9.3n.png){width="2.9195363079615047in" + height="3.011654636920385in"} height="2.777613735783027in"} + + ------------------------------------------------------------------------------------------------------------- + +Now use ***Climatic \> Dates \> Make Date*** to make a new Date column +from the Rwanda hourly column, Fig. 9.3o. + + ------------------------------------------------------------------------------------------------------------- + ***Fig. 9.3o*** ***Fig. 9.3p*** + ------------------------------------------------------ ------------------------------------------------------ + ![](figures/Fig9.3o.png){width="2.9332370953630797in" ![](figures/Fig9.3p.png){width="3.1684503499562555in" + height="2.824397419072616in"} height="2.5948917322834646in"} + + ------------------------------------------------------------------------------------------------------------- + +Finally generate Tmax and Tmin, on a daily basis, from the hourly +values, ready to use, or to compare with station data. First +***right-click*** and make the ***lon and lat columns into factors***. +The hourly data are now roughly as in Fig. 9.3p + +Complete the ***Prepare \> Column: Reshape \> Column Summaries*** +dialogue as shown in Fig. 9.3q. As these are temperatures the daily +maximum and minimum are calculated. The resulting worksheet, Fig. 9.3r, +has a more reasonable 100,000 rows of data at the 9 gridpoints. + + ------------------------------------------------------------------------------------------------------------- + ***Fig. 9.3q*** ***Fig. 9.3r Resulting daily data*** + ------------------------------------------------------ ------------------------------------------------------ + ![](figures/Fig9.3q.png){width="3.1482884951881016in" ![](figures/Fig9.3r.png){width="2.9195363079615047in" + height="3.011654636920385in"} height="2.777613735783027in"} + + ------------------------------------------------------------------------------------------------------------- + +## The IRI Data Store + +A third source of gridded data considered here is the IRI Data Library. +IRI is the International Research Institute for Climate and Society +based in Colombia University, USA. The website for their data library is +[[http://iridl.ldeo.columbia.edu/]{.underline}](http://iridl.ldeo.columbia.edu/) +, Fig. 9.4a. The IRI Data Store is a large repository of climate data +from a wide variety of sources. In many cases, the IRI Data Store is not +the only, or primary, source of the data, however the IRI Data Store +provides a simple consistent way of freely downloading from a large set +of sources, and crucially allows for selecting sub-regions. + +As well as downloading from the website, R-Instat includes a dialog to +directly download and import some of the common data from the IRI Data +Store. We demonstrate both methods here, using the R-Instat dialog to +download CHIRPS daily rainfall estimates and the IRI Data Store website +to download information on ENSO and sea surface temperatures. + +### Downloading directly from R-Instat + +Climate Hazards Group InfraRed Precipitation with Station data (CHIRPS), +produced by Climate Hazards Center UC Santa Barbara, USA, is a +near-global gridded rainfall data set, available from 1981 to +near-present with a spatial resolution of 0.05°. It is constructed by +combining satellite imagery and in-situ station data, and is available +on a daily, dekad and monthly basis. It's website is here +[[https://www.chc.ucsb.edu/data/chirps]{.underline}](https://www.chc.ucsb.edu/data/chirps) +but the data is more easily available to download and subset from the +IRI Data Store. It is an example of one of the datasets available to +download directly from R-Instat. + +In R-Instat go to ***Climatic \> File \> Import from IRI Data +Library***, fig xxx. First select "UCSB CHIRPS" as the ***Source***. We +will download the daily data with the highest resolution available, +hence choose "Daily Precipitation 0.05 degree" as the ***Data***, fig +xxx. Source shows a limited set of data sources available in the IRI +Data Store which we think will be most commonly used by R-Instat users. +If there is a dataset from the IRI Data Store that you commonly use and +think we should add, please let us know and we can consider adding it to +the dialog. + +The next two sections of the dialog allow for choosing a subset of time +or location. By default, "Entire Range" is selected for the data range. +For CHIRPS, this means 1981 to near-present. We will use this option, +but if you want a shorter time period choose "Custom Range" and select +the "From" and "To" dates. The Location Range allows you to choose an +area defined by longitude and latitude limits, or a single point, which +will extract the nearest grid point to the location you provide. Let's +first choose a single point for Kigali, Rwanda at longitude 30.1 and +latitude -1.95, fig xxx. + +The dialog will connect to the IRI Data Library and download the +requested data to your machine as a NetCDF file (.nc), a common format +for gridded data (CM SAF and C3S Climate Data Store data are also +provided in this format). Click ***Browse*** to choose where the +download data will be saved to or accept the default of your Documents +folder. Choose an appropriate name for the new data frame. Now, click +***Ok*** to download and import the data into R-Instat. It may take some +time for the request to be processed (up to 30 minutes), particularly +for requests that are for a long time period since data are usually +stored in separate files for each time point. However, this does not +mean the download will be a large file and the time can vary depending +on how busy the IRI Data Library servers are. While waiting, you will +see the R-Instat waiting dialog and the download progress bar. Do not +worry if the progress bar does not move forward, this just means the +request is still being processed. Once the request has been processed, +the download will usually be small and take very little time. For +example, this request should result in a download file of size \~0.1MB. + +After finishing you will see the data imported into R-Instat, fig xxx. +The NetCDF file has been downloaded to the location chosen on the dialog +(Documents by default) and the file has been imported into a data frame +in R-Instat. The data frame has five columns. X and Y are the location +and this should be constant since we requested a single point. Notice +that the value in Y is not exactly what we request. It is -1.97 and we +request -1.95. This is because the closed grid point in the CHIRPS data +grid to the provided location is selected. .T is time as a number and +T_date is a more useful column that is created by R-Instat when +importing as a Date column. prcp is precipitation. We can confirm this +by looking at the column metadata: ***View \> Column Metadata***. Scroll +to the end to see the "standard_name" and "units" columns which confirm +what each column represents and its units, fig xxx. Click ***View \> +Column Metadata*** again to close the metadata. We can see that each row +in the data represents a single day, starting on 1981-01-01. Use +***Describe \> One Variable \> Summaries***, and select all columns to +see a summary of the data. The output is shown in fig xxx. We see that X +and Y are constant, as expected. .T is numeric and not that useful, but +T_date show the data ranges from 1981-01-01 to 2020-08-31 (as of October +2020, usually 1 or 2 months behind the current date). prcp shows a +sensible set of summaries for daily rainfall values. This is useful to +do to confirm that the request is as you expected. For example, if X and +Y are not constant but you wanted just a single point, then you may not +have done the request correctly. + +Notice that the data file is also stored on your machine in the folder +you chose. For example, in Documents my file is called +ucsb_chirps7f14482329.nc. If you need to import this data again, you can +now use the file directly, without requesting it again from the IRI Data +Store. See section xxx on how to import NetCDF files. + +This data is useful for comparison with a single station in Kigali. We +often have data from multiple stations and would wish to extract gridded +data at each of the station locations. One way to do this would be to +make separate requests for each station location using the Import from +IRI Data Library multiple times. However, this becomes time consuming +for many stations, particularly if the processing time is slow. Another +option is to do a single request and download data for an area that +covers all the station locations and then afterwards extract the data +for the required locations. + +So let's to this by download the same data for an area that covers +Rwanda instead of a single point. This will be a larger download file +\~280MB but should not take much longer to process. If you have an +internet connection able to download \~300MB of data then try the next +steps below. If not, then this is just for reading. + +Go back to the ***Import from IRI Data Library*** dialog. The +***Source***, ***Data*** and ***Date Range*** options remain the same. +Change the ***Location Range*** option from "Point" to "Area" and enter +the values: longitude: min 28.5, max 30.5, latitude: min -2.5, max -1.4. +This area covers the four stations in Rwanda found in the R-Instat +Library. Choose the location to save the download or use the same +location. Now, the data request is for approximately a 2 degrees by 1 +degree area, which will give approximately (2 / 0.05) x (1 / 0.05) = 40 +x 20 = 800 grid points, since the resolution is 0.05 degrees. We do not +want to directly import all 800 grid points into R-Instat as this would +be equivalent to 800 station records for 40 years. Instead, we want to +download the data and then extract only a few grid points of interest +afterwards. So we will check the option for "Don't import data after +downloading". This removes the new data frame name as it will not import +into R-Instat but will just download to your machine. Now click ***Ok*** +and it may take a similar amount of time to complete. + +After finishing you will not see any change in R-Instat but the file +will be downloaded to the chosen folder. We can now use the dialog at +***Climatic \> File \> Import & Tidy NetCDF*** to import a subset of the +grid points based on station locations. This is shown in section xxx. + +### Download from the IRI Data Store + +As examples, information on ENSO and sea surface temperatures are +accessed. The maproom also contains instructional information, so typing +ENSO into the search, Fig. 9.4a, provides useful information, including +the areas of the Pacific ocean associated with the NINO situations, Fig. +9.4b. Fig. 9.4b is accessed directly from +[[https://iridl.ldeo.columbia.edu/maproom/ENSO/Diagnostics.html]{.underline}](https://iridl.ldeo.columbia.edu/maproom/ENSO/Diagnostics.html) + + ------------------------------------------------------------------------------------------------------------ + ***Fig.9.4a IRI Data Library*** ***Fig. 9.4b NINO3.4*** + ------------------------------------------------------ ----------------------------------------------------- + ![](figures/Fig9.4a.png){width="3.8668733595800524in" ![](figures/Fig9.4b.png){width="2.130990813648294in" + height="2.70544072615923in"} height="2.7068285214348204in"} + + ------------------------------------------------------------------------------------------------------------ + +In Fig. 9.4a click on Data by Category, then on Climate Indices, Fig. +9.4c and choose Indices nino EXTENDED, Fig. 9.4d. + + ------------------------------------------------------------------------------------------------------------- + ***Fig. 9.4c*** ***Fig. 9.4d*** + ------------------------------------------------------ ------------------------------------------------------ + ![](figures/Fig9.4c.png){width="2.6998807961504814in" ![](figures/Fig9.4d.png){width="3.4260433070866143in" + height="2.4705489938757657in"} height="2.2284437882764654in"} + + ------------------------------------------------------------------------------------------------------------- + +Choose ***nino34***, in Fig. 9.4e and then go straight to ***data +files***. The next screen shows a variety of output formats, including +NetCDF, which you choose. + + ----------------------------------------------------------------------------------------------------------- + ***Fig. 9.4e*** ***Fig. 9.4f*** + ----------------------------------------------------- ----------------------------------------------------- + ![](figures/Fig9.4e.png){width="3.075055774278215in" ![](figures/Fig9.4f.png){width="2.899403980752406in" + height="3.0795778652668417in"} height="3.59878280839895in"} + + ----------------------------------------------------------------------------------------------------------- + +Now, in R-Instat, use File \> Open and Tidy NetCDF File. If you followed +the screens above, then browse for the file that was downloaded. +Otherwise there is a copy in the R-Instat library to March 2019, Fig. +9.4g. + + ------------------------------------------------------------------------------------------------------------ + ***Fig. 9.4g*** ***Fig. 9.4h*** + ----------------------------------------------------- ------------------------------------------------------ + ![](figures/Fig9.4g.png){width="2.841988188976378in" ![](figures/Fig9.4h.png){width="2.6477077865266843in" + height="2.867364391951006in"} height="3.06124343832021in"} + + ------------------------------------------------------------------------------------------------------------ + +The data are now imported into R-Instat, Fig. 9.4h. The time variable +has not been recognised as a date. You may wish to click on the I (for +information -- the metadata) and this will confirm that the column, +called T, is months since January 1960. If the fact that some values +appear the same in this column, then change the number of significant +figures in that column, from 3 to 5. + +The first value of T, in Fig. 9.4h is -1248. Dividing by 12 gives 104 +years, so the data start in January 1856! + +Use Climatic \> Dates \> Generate Dates, Fig. 9.4i. In Fig. 9.4i, change +the starting date to January 1856, the end date to March 2019 (if using +the library dataset), and the step to 1 Month. The resulting date column +is shown in Fig. 9.4j. + + ------------------------------------------------------------------------------------------------------------ + ***Fig. 9.4i*** ***Fig. 9.4j*** + ----------------------------------------------------- ------------------------------------------------------ + ![](figures/Fig9.4i.png){width="2.841988188976378in" ![](figures/Fig9.4j.png){width="2.6477077865266843in" + height="2.867364391951006in"} height="3.06124343832021in"} + + ------------------------------------------------------------------------------------------------------------ + +Countries have their own definition of when the NINO3.4 implies a year, +or season is El Niño, or La Niña, see +[[https://en.wikipedia.org/wiki/El_Ni%C3%B1o]{.underline}](https://en.wikipedia.org/wiki/El_Ni%C3%B1o), +some use the NINO3.4 value and others use NINo3, or even NINO1 and 2. +The site +[[http://www.bom.gov.au/climate/enso/enlist/index.shtml]{.underline}](http://www.bom.gov.au/climate/enso/enlist/index.shtml) +gives a detailed description of El Niño events since 1900, Fig. 9.4k, +with a companion page for La Niña. + + ------------------------------------------------------------------------------------------------------------ + ***Fig. 9.4k*** ***Fig. 9.4l*** + ----------------------------------------------------- ------------------------------------------------------ + ![](figures/Fig9.4k.png){width="3.470980971128609in" ![](figures/Fig9.4l.png){width="2.5918022747156604in" + height="2.1808070866141733in"} height="1.7213331146106736in"} + + ------------------------------------------------------------------------------------------------------------ + +The SSTs themselves are often used for seasonal forecasting. This is +illustrated with the SSTs for the Nino3.4 region. + +***Return to the main page***, Fig. 9.4a, then choose ***Data by +Category*** again, but this time, in Fig. 9.4c, choose ***Air-Sea +Interface***. In the resulting screen, choose the ***NOAA NCDC ERSST +version5***, Fig. 9.4l. + +In the resulting screen, Fig. 9.4m, choose ***anomalies*** and then +***Data Selection***. + + ------------------------------------------------------------------------------------------------------------ + ***Fig. 9.4m*** ***Fig. 9.4n*** + ----------------------------------------------------- ------------------------------------------------------ + ![](figures/Fig9.4m.png){width="2.991107830271216in" ![](figures/Fig9.4n.png){width="3.0622233158355208in" + height="2.34369750656168in"} height="2.5905457130358704in"} + + ------------------------------------------------------------------------------------------------------------ + +Set the ***time, attitude and longitude*** as shown in Fig. 9.4n and +then ***Restrict Ranges***. The part at the top of Fig. 9.4n should +change accordingly and you now press ***Stop Selecting***. + +Fig. 9.4m now has the three ranges added, in blue, Fig. 9.4o. Click on +Data Files to give the same as Fig. 9.4f, earlier. Choose the NetCDF +option again to download the file. + + ----------------------------------------------------------------------------------------------------------- + ***Fig. 9.4o*** ***Fig. 9.4p*** + ----------------------------------------------------- ----------------------------------------------------- + ![](figures/Fig9.4o.png){width="2.780994094488189in" ![](figures/Fig9.4p.png){width="3.290544619422572in" + height="1.8450831146106736in"} height="2.7998042432195978in"} + + ----------------------------------------------------------------------------------------------------------- + +Use the File \> Input and Tidy NetCDF File as in Fig. 9.4g. Then use the +Climatic \> Dates \> Generate Dates dialogue as shown in Fig. 9.4p. In +Fig. 9.4p, remember to change to the new data frame. Then set the +starting date to January 1921 and there are now 130 values (26 E-W, by 5 +N-S) at each time point. + +In Fig. 9.4p, if all is correct, the generated sequence should match the +length of the data frame. Once accepted, the resulting data frame is +shown in Fig. 9.4q. Here each pixel is a 2 degree square, so the first +row is the temperature anomaly round 120°W and 4°S for January 1921. + + ----------------------------------------------------------------------- + ***Fig. 9.4q*** + ----------------------------------------------------------------------- + ![](figures/Fig9.4q.png){width="2.993989501312336in" + height="3.175609142607174in"} + + ----------------------------------------------------------------------- + +## Using the CM SAF toolbox for NetCDF files + +The CM SAF toolbox is an R software package designed to process the +NetCDF files downloaded from EUMETSAT, Section 9.3. It is used on the +downloaded files from EUMETSAT (or from other organisations who have +NetCDF files). This may be all you need, if your interest is in some +products from the EUMETSAT data. Or it may be before using R-Instat if +your interest is in comparing station and satellite data. + +## Defining ENSO + +See +[[https://www.ncdc.noaa.gov/teleconnections/enso/indicators/sst/]{.underline}](https://www.ncdc.noaa.gov/teleconnections/enso/indicators/sst/) + +[Warm and cold phases are defined as a minimum of five consecutive +3-month running mean of SST anomalies +([[ERSST.v5]{.underline}](http://origin.cpc.ncep.noaa.gov/products/analysis_monitoring/ensostuff/ONI_v5.php)) in the Niño 3.4 region surpassing a threshold of +/- 0.5°C]{.mark} \ No newline at end of file