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Case description

In this exercise we will use Metview to explore the various ways ensemble forecast forecasts can be processed and visualised. The case we will investigate is related to a low pressure system crossing the UK on 10 August 2014: it caused high winds and heavy rain especially in the South-Western part of the country.

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The plots we want to produce with Metview are as follows:

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The first three plots show the precipitation forecast for the period of August 24 00UTC - 25 00UTC from various model runs preceding the event by 1, 3 and 5 days, respectively. The last plot shows the observed rainfall for the same period.

We will use both Macro and icons to  ....

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Verify that the data are as expected.

Remember to give your icons useful names!

Setting the map View

With a new Geographical View icon, set up a cylindrical projection with its area defined as

South/West/North/East: 43/-20/60/10

Set up a new Coastlines icon with the following:

• the land coloured in cream
• the coastlines thick black
• use grey grid lines at every 5 degrees.

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Evaluating the forecasts

In this part of the exercise we will create the plot shown below:

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In this plot each map contains the various forecasts for the maximum 10 m wind gust in a 6-hour period from various model runs:

• top left: the closest latest forecast to before the event
• top right: the forecast run 4 days before the event
• bottom left: the ensemble mean for the ENS ENS  forecast run 4 days before the event
• bottom right: the ensemble spread for the ENS forecasts run 4 days before the event

Setting the View

With a new Geographical View icon, set up a cylindrical projection with its area defined as

South/West/North/East: 43/-20/60/10

Set up a new Coastlines icon with the following:

• the land coloured in cream
• the coastlines thick black
• use grey grid lines at every 5 degrees.

Defining the layout

With a new Display Window icon define a 2x2 layout so that each plot should contain your view. 

Visualising the latest forecast

The GRIB file fc_latest_oper.grib contains the latest forecast run preceding the event. Drag it into the top left map and customise it with the wgust_shade Contouring icon and the title_oper Text Plotting icon. Animate through the fields to see the location of the areas heavily hit by the storm.

Visualising the operational forecast

The GRIB file fc_oper.grib contains the operational forecast run at 7 August 00 TC UTC (four 4 days before the event). Drag it into the top right map and customise it in the same way as the previous plot. You will see that the wind storm was not present in the forecast.

Visualising the ensemble mean

The GRIB file fc_pfens.grib contains the 50 perturbed and 1 control forecast member and the 50 perturbed members of the ENS (Ensemble Prediction System) run at 7 August 00 TC UTC (four 4 days before the event). We will compute and visualise the mean of the ensemble members to see how the ENS predicted the event. The computations will be done in using a Macro.

Create a new Macro and edit it. First, read the GRIB file in:

g=read("fc_pfens.grib")

Our GRIB contains three time steps (78, 84 , and 90 and 96 hours, respectively) and we would like to compute the ensemble mean for each one separately. To achieve this goal we will write a loop going through the time steps. First, define the fieldset that will contain the results:

e_mean=nil

Next, add this piece of code to define the loop (we store the time steps in a list).:

tsLst=[78,84,90,96]

loop step in tsLst

    ...your code will go here ...

end loop

Within the loop, first, read all the 51 ENS members for the given time step:

f=read(data: g,
		step: step
	)	

then Next, compute their mean with the mean() macro function:

f = mean(f)

We Last, add this field to the resulting fieldset:

e_mean = e_mean & f

By doing so the loop's body is completed. We finish the macro by returning the resulting fieldset:

return e_mean

Drag it your Macro into the bottom left map and customise it with the wgust_shade Contouring icon and the title_mean Text Plotting icon. You will see . You would also need a custom Text Plotting icon for the title. Take a copy of the one used for the previous plots (called title_oper) and tailor it to your needs. When you analyse the plot you will notice that the ensemble mean hints for higher wind speeds gusts in the our area of questioninterest.

Visualising the ensemble spread

The ensemble spread is the standard deviation of the perturbed forecast ENS members. You We can compute it in a very similar way to the ensemble mean. The only difference is that this time you we need to use the stdev() function instead of mean(). Now it is your task to write a Macro for it. Once you finished your Macro drag it into the bottom right map and customise it with the wgust_spread_shade Contouring icon and the spread_mean with a custom Text Plotting icon. You will see that the ensemble spread is fairly high in the investigated area indicating that ...

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Checking the probabilities

In this part we will estimate the risk of the wind gust being higher than certain thresholds: i.e. we will compute some probabilities.  We will write a macro to a certain threshold. We will compute the probability of the wind gust exceeding 22 m/s ,

So create a Macro and edit it. First, read the GRIB file with the perturbed forecasts in:

g=read("fc_pf.grib")

(about 80 km/h) and generate the plot shown below:

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We will compute the probabilities with a Macro in a very similar way as we did for the ensemble mean (and standard deviation). The difference is that this time we need to compute a Since this GRIB contains several time steps we need to write a loop to compute the probability for each time step individually. First, define the fieldset that will contain the resulting probabilities:

e_prob=nil

Next, we define the threshold for wind gust (in m/s units). We will store it in a variable:

val=22

Now we can process the fields in a loop going through the time steps:

tsLst=[84,90,96]

loop step in tsLst

    ...your code will go here ...

end loop

Next, compute the probability in as follows:

.

Now duplicate the ensemble mean Macro and edit it. Find the code line computing the mean and replace it with this code block:

f=f > val22	
f=100*mean(f)

Here the The first line turned set ech gridpoint hiegher value than val 1 and all the others zero, Last, add it to the resulting fieldset:

e_prob = e_prob & f

We finish the macro by returning the resulting fieldset:

return e_prob

in the code above, performs a logical operation on the fieldset and results in a new fieldset. In this new fieldset we have only 1s and 0s:

• the value is 1 in each gridpoint where the condition meets (i.e. the value is larger than the threshold)
• the value is 0 in all other gridpoints.

The second line simply derives the probability as the mean of these fields. We multiply the result by 100 to scale it into the 0-100 range for an easier interpretation.

Once you finished your Macro, visualise your Geographical View icon and drag the Macro into the  plot. Customise By using the return statement our Macro behaves as if it were a fieldset (GRIB file). Drag it into the bottom left map and customise it with the prob_shade Contouring icon and the title_prob . Also use a custom Text Plotting icon . You will see that the ensemble mean hints that high wind speed can happen.

Part 3: ensemble members

to define the title. As for the probabilities, you should see that there is some probability of high wind speeds.

Creating a stamp plot

In this part we will investigate the individual ENS members and create a plot showing them all for a given time step on the same page like this:

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This plot, for an obvious reason, is called a stamp plot. This is a complex plot so we will write a Macro to generate itWe will create a stamp plot for a selected timestep i.e. we will plot the all the 50 ENS members.

Create a new Macro and edit it. Drop your Geographical View and the Coastlines icons into the Macro editor. Once you've tidied up the code is generated and tidied up , define a 6x9 layout so that each plot should contain your view:

dw=plot_super_pagesuperpage(pages: mxn_layout(my_view,9,6))

Next, drop your wgust_shade Contouring icon into the Macro editor and tidy up the generated code. We will apply this icon to all the fields in the stamp plot.

Continue with reading in  Next, read the GRIB file with of the perturbed ENS forecasts in:

g=read("fc_pfens.grib")

Define a variable to hold the time step we want to plot:

step = 90

The stamp plot will be generated by plotting each perturbed forecast member into a separate map, so Since this GRIB contains several time steps we need to write a loop to compute the probability for each time step individually. First, define the fieldset that will contain the resulting probabilities:

e_prob=nil

Next, we define the timestep we want to plot. We will store it in a variable:

val=90

like this:

for i=1 to 50 do 

    ...your code will go here ...

end for

Within the loop, simply read the current perturbed forecast member for the given time step:

f=read(data: g,
		number: i,
		type: "pf",
		step: step
	  )	

Next, define a title. The available space for the title in the plot is confined (we need to squeeze more than 50 maps into a page!) so the title should be short:

title = mtext(text_line_1 : "PF: " & i)

Last, plot the field into the right map in our layout:

plot(dw[i],title,f,wgust_shade)

Having done so we have finished the code inside the loop. Now visualise your Macro (this will take a minute or so) and try to identify the ENS members predicting high wind speeds in our area.

Creating a spaghetti plot

We finish the case study by looking into the predictability of the large scale flow pattern by generating spaghetti plots from the same ENS run as we investigated before. In a spaghetti plot each ENS member is rendered into the same map using a single isoline value. The plot we want to generate is shown below (it contains the spaghetti plot for 500 hPa geopotential using the 560 gpm isoline value):

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This is a fairly complex plot and we will write a Macro to produce it.

Create a new Macro and edit it. Drop your Geographical View and the Coastlines icons into the Macro editor and change the map area to

[40,-40,70,20]

so that our map could show a larger (North Atlantic) area.

Next, define the contouring used for the "spaghetti" by dropping the cont_spag Contouring icon into the Macro. A code like this should be generated for you:

cont_spag = mcont(
	contour_label: "off",
	contour_level_selection_type	:	"level_list",
	contour_level_list	:	560,
	contour_line_colour: "blue",
	contour_highlight: "off"
 )

In this mcont() we turned contour labels off to keep the plot uncluttered and defined only a single contour value (for 560 gpm). 

Continue with reading in the GRIB file of the ENS forecasts used for the "spaghetti":

 g = read("spag_ens.grib")

The "spaghetti" will be generated by plotting each perturbed forecasts member as a separate layer into the same map. To achieve this goal we need to write a loop like this:Now we will

for i=1 to 50 do 

    ...your code will go here ...

end for

Within the loop, simply read all the perturbed forecast members for the given timestepall the time steps:

f=read(data: g,
		steptype: step"pf", 
		number: i
 )	

then compute their mean with the mean() macro functionBy default, if no title definition is specified, Metview adds a title line for each field in the plot. Since we are about to plot 50 fields into the same map this would result in 50 titles in the plot! To avoid having too many titles we use a custom Text Plotting icon:

title = mtext(
		text_line_1	: "memberValue: 560 " &i,
		text_font_size: 0.2 
	)

and add it to the resulting fieldset:

plot(dw[i],title,f,wgust_shade)	

We finish the macro by returning the resulting fieldset:

return e_mean

gpm T+<grib_info key='step' where='number=50' /> h" )

Here we used the where statement inside the grib_info tag (as described here)  to make the title appear for one member (the 50th member) only.

Last, plot the field with our contour settings and title:

plot(your_view,f,cont_spag,title) 

Having done so we have finished the code inside the loop. Now visualise your Macro (it will take half a minute or so) and animate through the steps to see how the spaghetti is spreading out over time.

Extra Work if You Have Time

Add more fields to the stamp plot

The stamp plot only shows the perturbed ENS members but there is still space left to display additional fields, as well. Try to add the control forecast (from ENS) and the operational forecast to it. Some hints:

• plot the control forecast into the 51st map (dw[51]). The control forecast is stored in the same file as the perturbed forecast members: fc_ens.grib. Read it in with this code:

  Code Block
  f = read(data: g, type: "cf", step: step)

• plot the operational forecast into the 52nd map (dw[52]). The operational forecast is stored in fc_oper.grib. Read it in with this code:

  Code Block
  f =read(source: "fc_oper.grib", step: step)

NOTE: While setting up these extra plots it is a good idea to temporarily comment out the loop processing the perturbed forecast members.

Add more fields to the spaghetti plot

The spaghetti plot only shows the perturbed ENS members. Try to add the control forecast (from ENS) and the operational forecast to it as well. You should use different isoline colours for them. Some hints:

• use a thick red contour line. The control forecast is stored in the same file as the perturbed forecast members: spag_ens.grib. Read it in with this code:

  Code Block
  f = read(data: g, type: "cf")

• use thick green contour line. The operational forecast is stored in spag_oper.grib. Read it in with this code:

  Code Block
  f = read("spag_oper.grib")

NOTE: While setting up these extra plots it is a good idea to temporarily comment out the loop processing the perturbed forecast membersBy using the return statement our Macro behaves as if it were a fieldset (GRIB file). Drag it into the bottom left map and customise it with the wgust_shade Contouring icon and the title_mean Text Plotting icon. You will see that the ensemble mean hints that high wind speed can happen.