In this tutorial we will demonstrate This tutorial demonstrates how to run a forward simulation with FLEXPART and how to visualise the results in various ways.
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forward' to start working. |
Running the simulation
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In this tutorial we will run a forward simulation by releasing some SO2 from the Icelandic volcano Eyjafjallajökull. |
The simulation itself is defined by the 'fwd_conc' FLEXPART Run icon and the 'rel_volcano' FLEXPART Release icon, respectively. Both these are encompassed in a single macro called 'fwfwd_condconc.mv'. For simplicity will use this macro to examine the settings in detail.
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#Run flexpart (asynchronous call!) r = flexpart_run( output_path : "result_fwd_conc", input_path : "../data", starting_date : 20120517, starting_time : 12, ending_date : 20120519, ending_time : 12, output_field_type : "concentrationconc", output_flux : "on", output_trajectory : "on", output_area : [40,-25,66,10], output_grid : [0.25,0.25], output_levels : [500,1000,2000,3000,4000,5000,75006000,7000,8000,9000,10000,11000,12000,13000,14000,15000], release_species : 8, releases receptors : "on"rel_volcano, receptor_names release_units : ["rec1mass","rec2"], receptor_latitudes : [60,56.9], receptor_longitudes : [6.43,-3.5], releases receptor_units : rel_volcano "mass" ) print(r) |
Here we defined both the input and output path paths and specified the simulation period, the output grid and levels as well. We also told FLEXPART to generate gridded mass concentration and flux fields and plume trajectories on output..
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The actual species that will be released is to release are defined as an integer number (for details about using the species see here). With the default species settings number 8 stands for SO2. |
If we run this macro (or alternatively right-click execute
the FLEXPART Run icon) the results (after a minute or so) will be available in folder 'result_fw_concfwd'. The computations were actually taken took place in a temporary folder then metview Metview copied the results to the output folder. If we open this older folder 'result_fwd' we will see two three files there:
- conc_s001.grib is a GRIB file containing the gridded concentration fields
- trflux_r1s001.csv grib is CSV a GRIB file containing the plume trajectoriesgridded flux fields
- log.txt is the log file generated by FLEXPART
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Please note that these are not the original outputs form FLEXTRA FLEXPART but were converted to formats more suitable ones for use in Metview. For details about the FLEXPART outputs please click here. |
Visualising gridded fields
To plot a particular parameter and level we need to filter the desired dataset from the resulting FLEXPART output file. Unfortunately, Metview's Grib Filter icon cannot handle these files (partly due to the local GRIB definition they use) so we need to use other means to cope with this task. For this reason and also to make FLEXPART output handling easier a set of Metview Macro Library Functions were developed. We will heavily use these functions in the examples below.
Inspecting the FLEXPART GRIB file
Before seeing the macro code to generate the plot we inspect the file itself we wanted to plot. Double-click on the 'conc_s001.grib' GRIB icon' in folder 'result_fw_conc' to start up the Grib Examiner. We can see that this file only contains "mdc" (=Mass density concentration) fields. We can find out further details about this parameter by setting the Dump mode to Namespace and Namespace to Parameter:
Generating the plot
The macro to visualise the concentration fields on a given level is 'plot_level.mv'.
First, we define the level (8000 m) and the parameter ("mdc") we want to plot. Then we call the Macro Library Function mvl_flexpart_read_hl() to extract the data to plot.
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dIn="result_fwd_conc/"
inFile=dIn & "conc_s001.grib"
lev=8000
par="mdc"
#Read fields on the given height level
g=mvl_flexpart_read_hl(inFile,par,lev,-1,1) |
Next, we define the contouring definition. The units we used here are ng m**-3 because for parameter "mdc" the native units (kg m**-3) are automatically scaled by the plotting library (see details about the this scaling for various FLEXPART GRIB fields here.
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#The contour levels
cont_list=[1,10,50,100,150,200,250,500,750,1000,2000,6000]
#Define contour shading
conc_shade = mcont(
legend : "on",
contour : "off",
contour_level_selection_type : "level_list",
contour_level_list : cont_list,
contour_label : "off",
contour_shade : "on",
contour_shade_method : "area_fill",
contour_shade_max_level_colour : "red",
contour_shade_min_level_colour : "RGB(0.14,0.37,0.86)",
contour_shade_colour_direction : "clockwise",
contour_method : "linear"
) |
Next, we build the title with mvl_flexpart_title(). Please note that we need to explicitly specify the plotting units!
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title=mvl_flexpart_title(g,0.3,"ng m**-3") |
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To process and visualise the results please see these pages:
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Finally we define the view with the map:
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#Define coastlines
coast_grey = mcoast(
map_coastline_thickness : 2,
map_coastline_land_shade : "on",
map_coastline_land_shade_colour : "grey",
map_coastline_sea_shade : "on",
map_coastline_sea_shade_colour : "RGB(0.89,0.89,0.89)",
map_boundaries : "on",
map_boundaries_colour : "black",
map_grid_latitude_increment : 5,
map_grid_longitude_increment : 5
)
#Define geo view
view = geoview(
map_area_definition : "corners",
area : [40,-25,66,9],
coastlines : coast_grey
) |
and generate the plot:
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plot(view,g,conc_shade,title) |
Having run the macro we will get a plot like this (after navigating to step 39h):
Computing and plotting total column mass
Using the same FLEXPART output as above we will compute and plot the total column integrated mass. The macro to use is 'plot_total.mv'.
First, we call mvl_flexpart_total_column() to perform the computations. The result is a fieldset containing "tcmd" fields with units of "kg m**-2".
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dIn="result_fwd_conc/"
inFile=dIn & "conc_s001.grib"
#Compute the total column integrated mass
g=mvl_flexpart_total_column(inFile,1)
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Next, we define the contouring. The "tcmd" fields are automatically scaled into "ng m**-2" for contouring (see here for details) but with the current value range it is better to use "g m**-2" units. To achieve it we simply multiply the "tcmd" fieldset with 1000:
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g=g*1000 |
The contour definition itself goes like this:
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cont_list=[0.0001,0.001,0.005,0.01,0.02,0.05,0.1,0.5]
#Define contour shading
conc_shade = mcont(
legend : "on",
contour : "off",
contour_level_selection_type : "level_list",
contour_level_list : cont_list,
contour_label : "off",
contour_shade : "on",
contour_shade_method : "area_fill",
contour_shade_max_level_colour : "red",
contour_shade_min_level_colour : "RGB(0.14,0.37,0.86)",
contour_shade_colour_direction : "clockwise",
contour_method : "linear",
grib_scaling_of_derived_fields : "off"
)
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Please note that by multiplying our fieldset by 1000 it became a derived fieldset. Since we do not want the automatic contour scaling to happen we need to set the contouring parameter grib_scaling_of_derived_fields
to "off".
Next, we build the title with mvl_flexpart_title(). Please note that we need to explicitly specify the plotting units!
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title=mvl_flexpart_title(g,0.3,"g m**-2") |
Finally we define the view with the map in the same way as above and generate the plot:
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plot(view,g,conc_shade,title) |
Having run the macro we will get a plot like this (after navigating to step 39h):
First, we define the parameter and time step for the cross section then call mvl_flexpart_read_hl() to extract the data. The result is a fieldset with units of "kg m**-3" that we need to explicitly convert to "ng m**-3" units for plotting since the automatic units scaling only works for map based plots.
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#Define level, parameter and step
lev=-1 #all levels
par="mdc"
step=48
#Get fields for all levels for a given step
g=mvl_flexpart_read_hl(inFile,par,lev,step,1)
#Scale into ng/m3 units
g=g*1000000000000
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Next, we define the cross section view:
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xs_view = mxsectview(
bottom_level : 0,
top_level : 16000,
line : [63.31,-25,63.31,9]
)
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Then, we define the contouring:
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#The contour levels
cont_list=[1,10,50,100,150,200,250,500,750,1000,2000,5000,7000]
#Define contour shading
conc_shade = mcont(
legend : "on",
contour : "off",
contour_level_selection_type : "level_list",
contour_level_list : cont_list,
contour_label : "off",
contour_shade : "on",
contour_shade_method : "area_fill",
contour_shade_max_level_colour : "red",
contour_shade_min_level_colour : "RGB(0.14,0.37,0.86)",
contour_shade_colour_direction : "clockwise",
contour_method: "linear"
) |
and finally generate the plot:
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plot(xs_view,g,conc_shade) |
Having run the macro we will get a plot like this: