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When I extract data from a netCDF file Reanalysis (variable pressure (SLP), 01/01/2014) the data is very high resolution (9km grid) which makes the resulting image quite noisy. I would like to put the data into a lower resolution grid (e.g. 1 degree). I'm trying to use the functions meshgrid and gridata, but inexperience am unable to make it work. Does anyone know how to solve? Thank you.

    from netCDF4 import Dataset
    import numpy as np
    from scipy.interpolate import griddata
    file = Dataset('slp_2014_01_01.nc', 'r')
    # Printing variables
    print ' '
    print ' '
    print '----------------------------------------------------------'
    for i,variable in enumerate(file.variables):
        print '   '+str(i),variable
        if i == 2:
            current_variable = variable
    print ' '
    print 'Variable: ', current_variable.upper()
    print 'File name:  ', file_name
    lat  = file.variables['lat'][:]
    lon  = file.variables['lon'][:]
    slp = file.variables['slp'][:]

    lon_i = np.linspace(lon[0], lon[len(REANALYSIS_lon)-1], num=len(lon)*2, endpoint=True, retstep=False)    
    lat_i = np.linspace(lat[0], lat[len(lat)-1], num=len(lat)*2, endpoint=True, retstep=False)

    lon_grid, lat_grid = np.meshgrid(lon_i,lat_i)

    temp_slp = np.asarray(slp).squeeze()
    new_slp = temp_slp.reshape(temp_slp.size)

    slp_grid = griddata((lon, lat), new_slp, (lon_grid, lat_grid),method='cubic')

As I mentioned, I tried to use the meshgrid and datagrid functions, but produced the following error:

Traceback (most recent call last): File "REANALYSIS_LOCAL.py", line 346, in
lon,lat,time,var,variavel_atual=netCDF_builder_local(caminho_netcdf_local,nome_arquivo,dt) File "REANALYSIS_LOCAL.py", line 143, in netCDF_builder_local
slp_grid = griddata((lon, lat), new_slp, (lon_grid, lat_grid),method='cubic')
File "/home/carlos/anaconda/lib/python2.7/site-packages/scipy/interpolate/ndgriddata.py", line 182, in griddata points = _ndim_coords_from_arrays(points)
File "interpnd.pyx", line 176, in scipy.interpolate.interpnd._ndim_coords_from_arrays (scipy/interpolate/interpnd.c:4064)
File "/home/carlos/anaconda/lib/python2.7/site-packages/numpy/lib/stride_tricks.py", line 101, in broadcast_arrays "incompatible dimensions on axis %r." % (axis,))
ValueError: shape mismatch: two or more arrays have incompatible dimensions on axis 0.

The dimensions of variables are:
lon: (144,)
lat: (73,)
lon_i: (288,)
lat_i: (146,)
lon_grid: (146, 288)
lat_grid: (146, 288)
new_slp: (10512,)

The values in new_slp are: new_slp: [ 102485. 102485. 102485. ..., 100710. 100710. 100710.]

The purpose is increase the values in the variables (lon, lat and slp), because the Reanalysis resolution is highter. Then, the resolution could be most detailed (more points).

For example: the variable lat have the points:

Original dimension variable lat: (73,)
lat: [ 90. 87.5 85. 82.5 80. 77.5 75. 72.5 70. 67.5 65. 62.5 60. 57.5 55. 52.5 50. 47.5 45. 42.5 40. 37.5 35. 32.5 30. 27.5 25. 22.5 20. 17.5 15. 12.5 10. 7.5 5. 2.5 0. -2.5 -5. -7.5 -10. -12.5 -15. -17.5 -20. -22.5 -25. -27.5 -30. -32.5 -35. -37.5 -40. -42.5 -45. -47.5 -50. -52.5 -55. -57.5 -60. -62.5 -65. -67.5 -70. -72.5 -75. -77.5 -80. -82.5 -85. -87.5 -90. ]

When I define the code line: lat_i = np.linspace(lat[0], lat[len(lat)-1], num=len(lat)*2, endpoint=True, retstep=False) I doubled the values of the lat variable la_i(146,)

lat _i: [ 90. 88.75862069 87.51724138 86.27586207 85.03448276 83.79310345 82.55172414 81.31034483 80.06896552 78.82758621 77.5862069
...
-78.82758621 -80.06896552 -81.31034483 -82.55172414 -83.79310345 -85.03448276 -86.27586207 -87.51724138 -88.75862069 -90. ]

The idea that I need is the same is available in this code, where x is lon, y is lat and slp is z.
from scipy.interpolate import griddata import numpy as np import matplotlib.pyplot as plt

x=np.linspace(1.,10.,20)
y=np.linspace(1.,10.,20)
z=z = np.random.random(20)
xi=np.linspace(1.,10.,40)
yi=np.linspace(1.,10.,40)

X,Y= np.meshgrid(xi,yi)

Z = griddata((x, y), z, (X, Y),method='nearest')

plt.contourf(X,Y,Z)

2 Answers 2

3

Depending on Your final purpose, You may use cdo to regrid the whole file

cdo remapbil,r360x180 infile outfile

or just plot every second or third value from original file like this:

plt.pcolormesh(lon[::2,::2],lat[::2,::2],var1[::2,::2])

The error message You show just says that dimensions do not much, just print the shape of your variables before the error appears and try to get it working.

Why Your code does not work? Your chosen method requires input coordinates as lon,lat pairs for data points, not mesh coordinates. If You have data points with shape 10000, your coordinates must be with the shape (10000,2), not (100,100). But as griddata is meant for unstructured data, it will not be efficient for Your purpose, I suggest using something like scipy.interpolate.RegularGridInterpolator

But anyway, if You need to use the interpolated data more than once, I suggest creating new netCDF files with cdo and process them, instead of interpolating data each time You run Your script.

3
  • thanks for you answer... but I added more details about my purpose/what I need to do. Commented Sep 28, 2015 at 19:16
  • Ok, first You say You want 1 degree resolution instead of 9 km? But then You create new coordinates (lon_i, lat_i) which are twice as large as initial array, thus getting "finer" resolution?! You could still do this with cdo, which is developed for exactly this purpose.
    – kakk11
    Commented Sep 29, 2015 at 6:00
  • I edited my first answer to explain why Your code does not seem to work.
    – kakk11
    Commented Sep 29, 2015 at 6:07
0

Thanks for your help. Really, my problem was about dimensions. I'm learning to work with oceanographic data. So, I solved the problem with this code.

lonbounds = [25,59]
latbounds = [-10,-33]

#longitude lower and upper index
lonli = np.argmin(np.abs(lon - lonbounds[0]))
lonui = np.argmin(np.abs(lon - lonbounds[1]))  

#latitude lower and upper index
latli = np.argmin(np.abs(lat - latbounds[0]))
latui = np.argmin(np.abs(lat - latbounds[1])) 

#limiting of the interest region/data
lon_f = file.variables['lon'][lonli:lonui]  
lat_f = file.variables['lat'][latli:latui] 
slp_f = file.variables['slp'][0,latli:latui,lonli:lonui] 

#creating a matrix with the filtered data (area to be searched) for use in gridData function of python
lon_f_grid, lat_f_grid = np.meshgrid(lon_f,lat_f)

#adjusting the data (size 1) for use in gridData function of python
lon_f1 = lon_f_grid.reshape(lon_f_grid.size)
lat_f1 = lat_f_grid.reshape(lat_f_grid.size)
slp_f1 = slp_f.reshape(slp_f.size)

#increasing the resolution of data (1000 points) of longitude and latitude for the data to be more refined
lon_r = np.linspace(lon_f[0], lon_f[len(lon_f)-1], num=1000, endpoint=True, retstep=False)
lat_r = np.linspace(lat_f[0], lat_f[len(lat_f)-1], num=1000, endpoint=True, retstep=False)

#creating a matrix with the filtered data (area to be searched) and higher resolution for use in gridData function of python
lon_r_grid, lat_r_grid = np.meshgrid(lon_r,lat_r)

#applying gridata that can be generated since pressure (SLP) with higher resolution.
slp_r = griddata((lon_f1,lat_f1),slp_f1,(lon_r_grid,lat_r_grid),method='cubic')

Hugs, Carlos.

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