Working with Multidimensional Coordinates

Author: Ryan Abernathey

Many datasets have physical coordinates which differ from their logical coordinates. Xarray provides several ways to plot and analyze such datasets.

%matplotlib inline
import numpy as np
import pandas as pd
import xarray as xr
import cartopy.crs as ccrs
from matplotlib import pyplot as plt

print("numpy version  : ", np.__version__)
print("pandas version : ", pd.__version__)
print("xarray version   : ", xr.version.version)
('numpy version  : ', '1.11.0')
('pandas version : ', u'0.18.0')
('xarray version   : ', '0.7.2-32-gf957eb8')

As an example, consider this dataset from the xarray-data repository.

! curl -L -O https://github.com/pydata/xarray-data/raw/master/RASM_example_data.nc
ds = xr.open_dataset('RASM_example_data.nc')
ds
<xarray.Dataset>
Dimensions:  (time: 36, x: 275, y: 205)
Coordinates:
  * time     (time) datetime64[ns] 1980-09-16T12:00:00 1980-10-17 ...
    yc       (y, x) float64 16.53 16.78 17.02 17.27 17.51 17.76 18.0 18.25 ...
    xc       (y, x) float64 189.2 189.4 189.6 189.7 189.9 190.1 190.2 190.4 ...
  * x        (x) int64 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 ...
  * y        (y) int64 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 ...
Data variables:
    Tair     (time, y, x) float64 nan nan nan nan nan nan nan nan nan nan ...
Attributes:
    title: /workspace/jhamman/processed/R1002RBRxaaa01a/lnd/temp/R1002RBRxaaa01a.vic.ha.1979-09-01.nc
    institution: U.W.
    source: RACM R1002RBRxaaa01a
    output_frequency: daily
    output_mode: averaged
    convention: CF-1.4
    references: Based on the initial model of Liang et al., 1994, JGR, 99, 14,415- 14,429.
    comment: Output from the Variable Infiltration Capacity (VIC) model.
    nco_openmp_thread_number: 1
    NCO: 4.3.7
    history: history deleted for brevity

In this example, the logical coordinates are x and y, while the physical coordinates are xc and yc, which represent the latitudes and longitude of the data.

print(ds.xc.attrs)
print(ds.yc.attrs)
OrderedDict([(u'long_name', u'longitude of grid cell center'), (u'units', u'degrees_east'), (u'bounds', u'xv')])
OrderedDict([(u'long_name', u'latitude of grid cell center'), (u'units', u'degrees_north'), (u'bounds', u'yv')])

Plotting

Let’s examine these coordinate variables by plotting them.

fig, (ax1, ax2) = plt.subplots(ncols=2, figsize=(14,4))
ds.xc.plot(ax=ax1)
ds.yc.plot(ax=ax2)
<matplotlib.collections.QuadMesh at 0x118688fd0>
/Users/rpa/anaconda/lib/python2.7/site-packages/matplotlib/collections.py:590: FutureWarning: elementwise comparison failed; returning scalar instead, but in the future will perform elementwise comparison
  if self._edgecolors == str('face'):
../_images/xarray_multidimensional_coords_8_2.png

Note that the variables xc (longitude) and yc (latitude) are two-dimensional scalar fields.

If we try to plot the data variable Tair, by default we get the logical coordinates.

ds.Tair[0].plot()
<matplotlib.collections.QuadMesh at 0x11b6da890>
../_images/xarray_multidimensional_coords_10_1.png

In order to visualize the data on a conventional latitude-longitude grid, we can take advantage of xarray’s ability to apply cartopy map projections.

plt.figure(figsize=(14,6))
ax = plt.axes(projection=ccrs.PlateCarree())
ax.set_global()
ds.Tair[0].plot.pcolormesh(ax=ax, transform=ccrs.PlateCarree(), x='xc', y='yc', add_colorbar=False)
ax.coastlines()
ax.set_ylim([0,90]);
../_images/xarray_multidimensional_coords_12_0.png

Multidimensional Groupby

The above example allowed us to visualize the data on a regular latitude-longitude grid. But what if we want to do a calculation that involves grouping over one of these physical coordinates (rather than the logical coordinates), for example, calculating the mean temperature at each latitude. This can be achieved using xarray’s groupby function, which accepts multidimensional variables. By default, groupby will use every unique value in the variable, which is probably not what we want. Instead, we can use the groupby_bins function to specify the output coordinates of the group.

# define two-degree wide latitude bins
lat_bins = np.arange(0,91,2)
# define a label for each bin corresponding to the central latitude
lat_center = np.arange(1,90,2)
# group according to those bins and take the mean
Tair_lat_mean = ds.Tair.groupby_bins('xc', lat_bins, labels=lat_center).mean()
# plot the result
Tair_lat_mean.plot()
[<matplotlib.lines.Line2D at 0x11cb92e90>]
../_images/xarray_multidimensional_coords_14_1.png

Note that the resulting coordinate for the groupby_bins operation got the _bins suffix appended: xc_bins. This help us distinguish it from the original multidimensional variable xc.