LSA-SAF Satellite HDF5 Plot in Python Cartopy

Question

I have some LSA-SAF HDF5 file data and I'm hoping to finally plot it in Python with Cartopy. I have zero experience with HDF5 files so I could be barking up the wrong tree here, but I can plot the data and the map. The major issue is that the projections don't line up. I've tried messing with the projections in both the subplot and the imshow transform argument. Since the MSG data appears to not be geolocated maybe I can't do what I was hoping easily.

My code:

FILE_NAME = 'HDF5_LSASAF_MSG_LAI_MSG-Disk_201806010000.h5' #LAI

crs = ccrs.Geostationary(central_longitude=0.0,satellite_height= 35785831)
crs2 = ccrs.PlateCarree(central_longitude=0.0) #central_longitude=0.0
fig = plt.figure(figsize=(10, 12))
ax = fig.add_subplot(1, 1, 1, projection=crs)
f = h5py.File(FILE_NAME, mode='r')
key_list = f.keys()

key_list2 = []
key_list2.append(key_list[0])

for key in key_list2:
    print(key)
    matrix = f.get(key)
    ax.add_feature(cfeature.COASTLINE.with_scale('50m'), linewidth=0.75)
    ax.add_feature(cfeature.BORDERS.with_scale('50m'), linewidth=0.5)
    ax.add_feature(cfeature.OCEAN.with_scale('50m'),alpha=0.2)
    cmap=cm.YlGn
    cmap.set_bad(alpha=0.0)

    img_extent = (-65,65,-65,65)

    ax.imshow(matrix[:], cmap=cmap, norm=colors.Normalize(vmin=-1.0,             
      vmax=7000.0), origin='upper',extent=img_extent,transform=crs2)

plt.show()

I had a similar problem when I was trying to plot GOES-16 data and it was resolved with satellite height calculations for lat and lon. I don't know enough about the HDF5 file hierarchy to find similar data for the MSG geostationary satellite. Any insight into whether this can be accomplished and/or HDF5 data would be very appreciated.

Answer 1

Just as tda mentioned I was successful with gdal as well. Here I was using the FAPAR product.

in_pathfiles = '/path/to/HDF5 files/*FAPAR*.h5' # Where .hdf5 files exist
out_pathfiles = '/path/to/new geotiff files/' # Where the new .tif file will be placed
myfiles = glob.glob(in_pathfiles) #list of all files

for f in myfiles:
    print(f),"\n"
    filename = f.split("\\")[-1]
    print "filename",out_pathfiles+filename,"\n"

    f_out = filename[:-3] + ".tif"  # splitting the .hd5 off the fileneame and making a new .tif filename
    print "f_out",out_pathfiles+f_out,"\n"

    f_rep = out_pathfiles+filename[:-3] + "_rep.tif" # create a new final .tif filename for reprojection
    print "f_rep",f_rep,"\n"

# Translating the satellite height and ellipitical values to xy values and filling the new _rep.tif file
# from the original .h5 file
os.system('gdal_translate -of GTiff -a_srs "+proj=geos +h=35785831 +a=6378169 +b=6356583.8 +no_defs"\
-a_ullr  -5568748.27576  5568748.27576 5568748.27576 -5568748.27576 "HDF5:'+ filename + '://FAPAR '+ f_out)

# Mapping the new values and filling the new _rep.tif file
os.system('gdalwarp -ot Float32 -s_srs "+proj=geos +h=35785831 +a=6378169 +b=6356583.8 +no_defs"\
-t_srs EPSG:4326 -r near -of GTiff ' + f_out + ' ' + f_rep)

Plot:

# enable gdal exceptions (instead of the silent failure which is gdal default)
gdal.UseExceptions()

fname = "/path/to/rep.tif file/"
ds = gdal.Open(fname)

print( "[ RASTER BAND COUNT ]: ", ds.RasterCount)
cols = ds.RasterXSize
print('cols = ',cols)
rows = ds.RasterYSize
print(' rows = ', rows)
bands = ds.RasterCount
print('bands = ', bands)
driver = ds.GetDriver().LongName
print('driver =', driver)

print('MetaData = ',ds.GetMetadata())

Meta = ds.GetMetadata()
#print Meta.values()
Product = Meta.values()[3]
print Product

# print various metadata for the image
geotransform = ds.GetGeoTransform()
if not geotransform is None:
    print ('Origin = (',geotransform[0], ',',geotransform[3],')')
    print ('Pixel Size = (',geotransform[1], ',',geotransform[5],')')
proj = ds.GetProjection()
print proj
inproj = osr.SpatialReference()
inproj.ImportFromWkt(proj)

print('inproj = \n', inproj)
data = ds.ReadAsArray()
crs = ccrs.Geostationary(central_longitude=0.0)
crs2 = ccrs.PlateCarree(central_longitude=0.0)
fig = plt.figure(figsize=(10, 12))
ax = fig.add_subplot(1, 1, 1, projection=crs)

ax.add_feature(cfeature.COASTLINE.with_scale('50m'), linewidth=0.75)
ax.add_feature(cfeature.BORDERS.with_scale('50m'), linewidth=0.5)
ax.add_feature(cfeature.OCEAN.with_scale('50m'),alpha=0.2)

cmap=cm.YlGn
cmap.set_bad(alpha=0.0)
#ax.set_extent([-60,60,-60,60])
img_extent = (-81.26765645410755,81.26765645410755,-74.11423113858775,74.11423113858775)
ax.imshow(data, cmap=cmap, norm=colors.Normalize(vmin=-1.0, vmax=7000.0), origin='upper'
         ,extent=img_extent,transform=crs2) 

plt.show()

Plot a new region and masked array for where data is 0. This allowed me to display the oceans and other areas where the data wasn't relevant:

fig = plt.figure(figsize=(10, 12))

 # enable gdal exceptions (instead of the silent failure which is gdal default)
gdal.UseExceptions()

fname = "/path/to/rep.tif file/"
ds = gdal.Open(fname)

Meta = ds.GetMetadata()

Product = Meta.values()[3]
#print Product

Date = Meta.values()[38]
Date_End = Date[:8]

geotransform = ds.GetGeoTransform()
data = ds.ReadAsArray()
data = np.ma.masked_where(data <= -1, data)

crs = ccrs.Geostationary(central_longitude=0.0)
crs2 = ccrs.PlateCarree(central_longitude=0.0)

ax = fig.add_subplot(1, 1, 1, projection=crs2)
gl = ax.gridlines(crs=crs2, draw_labels=True,
    linewidth=2, color='gray', alpha=0.5, linestyle='--')
gl.xlabels_top = False
gl.ylabels_left = False

ax.add_feature(cfeature.COASTLINE.with_scale('50m'), linewidth=0.75)
ax.add_feature(cfeature.BORDERS.with_scale('50m'), linewidth=0.5)

cmap=cm.YlGn
cmap.set_bad(alpha=0.0)

ax.set_extent([5,40,-10,8]) # Congo

img_extent = (-81.26765645410755,81.26765645410755,-74.11423113858775,74.11423113858775)

cf = ax.imshow(data, cmap="RdYlGn", origin='upper'
    ,extent=img_extent,transform=crs2)

cbar = plt.colorbar(cf, orientation='horizontal')
ax.add_feature(cfeature.OCEAN.with_scale('50m'),alpha=0.5)

plt.show()