Map projection and forced interpolation

I have a weird behaviour using different projections of Basemap.

The measurementgrid that I want to plot onto a worldmap is of shape [181,83]. That means I have values for each 2°/2° point, ranging from -180° - 180° longitude and -82° - 82° latitude.

``````from mpl_toolkits.basemap import Basemap
import numpy as np
measurementgrid = np.random.random_sample((181,83))
m = Basemap(projection='cyl',llcrnrlon=-180, llcrnrlat=-82, urcrnrlon=180, urcrnrlat=82, resolution='l')
m.drawcoastlines()
m.drawparallels(np.arange(-90,90,30),labels=[1,0,0,0])
m.drawmeridians(np.arange(-180,180,45), labels=[0,0,0,1])
data, x, y = m.transform_scalar(measurementgrid.T, lons=np.arange(-180,182,2), lats=np.arange(-82,84,2), nx = 181, ny = 83, returnxy=True, order=0)
m.imshow(data, origin='lower', interpolation='none')
``````

Using the cylindrical projection the returned data grid equals the measurementgrid and everthing is fine. If I change the projection to "mill", the resulting interpolated data differs from its origin.

Is there a way to plot the measurement grid as it is but with respect to the changing projection?

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Your example code doesn't show where you are getting `measurementgrid` from, (it also doesn't show `import numpy as np` but I managed to guess that! – Steve Barnes Aug 12 '13 at 12:09
Fixed it. Thanks! – nit Aug 12 '13 at 15:40
Can I suggest posting your fix to help anybody else who is having a similar problem! – Steve Barnes Aug 12 '13 at 17:47
I haven't fixed the problem, but I edited my post according to your suggestion. So the problem is still present! – nit Aug 13 '13 at 13:15

First off, I'd encourage you to start using pcolormesh, rather than imshow. Pcolormesh should be your go-to visualisation tool when trying to plot gridded data in boxes (as contourf is when drawing gridded data as iso-valued areas).

To get using pcolormesh, you should pass through the coordinates of the x and y corners of your data, so:

``````x = np.linspace(-180, 180, 182)
y = np.linspace(-90, 90, 84)
m.pcolormesh(x, y, data)
``````

But with Basemap, you should always transform the coordinates into the map's coordinate system - ultimately this could potentially mean that both the x and y coordinates need to be 2 dimensional arrays, so we do that and convert:

``````x = np.linspace(-180, 180, 182)
y = np.linspace(-90, 90, 84)
x, y = np.meshgrid(x, y)
converted_x, converted_y = m(x, y)
m.pcolormesh(converted_x, converted_y, data)
``````

What that means is that you can now go ahead and change the projection, and your data will be plotted in the right place. For instance, I changed the projection to "robin" (Robinson) and got the following picture:

Unfortunately, pcolormesh is for contiguous blocks of data, which if you pick a projection which does not share the same central longitude (aka "lon_0") then you will get bad results. For instance, I changed the projection to `projection='robin',lon_0=180` and got the following picture:

That is because the dateline is not currently handled by Basemap, and as far as I can see, without a major re-write - never will be.

The good news is that this is an area which has bothered me for a long time, so I started writing a new package to handle this, and many other quirks of mapping for scientific visualisation. The result is a new package, called cartopy, which does a lot more work for you so that things like the dateline "just work":

``````import numpy as np
import cartopy.crs as ccrs
import matplotlib.pyplot as plt

x = np.linspace(-180, 180, 182)
y = np.linspace(-90, 90, 84)
measurement_grid = np.random.random_sample((83, 181)) * y[:-1, np.newaxis] ** 2

plt.axes(projection=ccrs.Robinson(central_longitude=180))
plt.pcolormesh(x, y, measurement_grid, transform=ccrs.PlateCarree())
plt.gca().coastlines()
plt.show()
``````

Whilst I'm not suggesting that you should change to cartopy now (installation and performance are still work in progress) - it is worth knowing that the package exists, and I expect in the future will become more and more attractive as you encounter these kinds of issues. http://scitools.org.uk/cartopy/docs/latest

It is also worth pointing out that a lot of the problems that occur with scientific visualisation of gridded data come in the handling of the data, its coordinates and their underlying coordinate systems, so another package has been written which implements a data model to encapsulate all of this complex information into a single object which can then be passed around to plotting routines for simple interfacing. Again, I'd encourage to you take a look at it http://scitools.org.uk/iris/docs/latest.

HTH

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