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Calculate a spatial mean of xarray's DataArray
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# -*- coding: utf-8 -*- | |
"""Operations on cartesian geographical grid.""" | |
import numpy as np | |
EARTH_RADIUS = 6371000.0 # m | |
def _guess_bounds(points, bound_position=0.5): | |
""" | |
Guess bounds of grid cells. | |
Simplified function from iris.coord.Coord. | |
Parameters | |
---------- | |
points: numpy.array | |
Array of grid points of shape (N,). | |
bound_position: float, optional | |
Bounds offset relative to the grid cell centre. | |
Returns | |
------- | |
Array of shape (N, 2). | |
""" | |
diffs = np.diff(points) | |
diffs = np.insert(diffs, 0, diffs[0]) | |
diffs = np.append(diffs, diffs[-1]) | |
min_bounds = points - diffs[:-1] * bound_position | |
max_bounds = points + diffs[1:] * (1 - bound_position) | |
return np.array([min_bounds, max_bounds]).transpose() | |
def _quadrant_area(radian_lat_bounds, radian_lon_bounds, radius_of_earth): | |
""" | |
Calculate spherical segment areas. | |
Taken from SciTools iris library. | |
Area weights are calculated for each lat/lon cell as: | |
.. math:: | |
r^2 (lon_1 - lon_0) ( sin(lat_1) - sin(lat_0)) | |
The resulting array will have a shape of | |
*(radian_lat_bounds.shape[0], radian_lon_bounds.shape[0])* | |
The calculations are done at 64 bit precision and the returned array | |
will be of type numpy.float64. | |
Parameters | |
---------- | |
radian_lat_bounds: numpy.array | |
Array of latitude bounds (radians) of shape (M, 2) | |
radian_lon_bounds: numpy.array | |
Array of longitude bounds (radians) of shape (N, 2) | |
radius_of_earth: float | |
Radius of the Earth (currently assumed spherical) | |
Returns | |
------- | |
Array of grid cell areas of shape (M, N). | |
""" | |
# ensure pairs of bounds | |
if ( | |
radian_lat_bounds.shape[-1] != 2 | |
or radian_lon_bounds.shape[-1] != 2 | |
or radian_lat_bounds.ndim != 2 | |
or radian_lon_bounds.ndim != 2 | |
): | |
raise ValueError("Bounds must be [n,2] array") | |
# fill in a new array of areas | |
radius_sqr = radius_of_earth ** 2 | |
radian_lat_64 = radian_lat_bounds.astype(np.float64) | |
radian_lon_64 = radian_lon_bounds.astype(np.float64) | |
ylen = np.sin(radian_lat_64[:, 1]) - np.sin(radian_lat_64[:, 0]) | |
xlen = radian_lon_64[:, 1] - radian_lon_64[:, 0] | |
areas = radius_sqr * np.outer(ylen, xlen) | |
# we use abs because backwards bounds (min > max) give negative areas. | |
return np.abs(areas) | |
def grid_cell_areas(lon1d, lat1d, radius=EARTH_RADIUS): | |
""" | |
Calculate grid cell areas given 1D arrays of longitudes and latitudes | |
for a planet with the given radius. | |
Parameters | |
---------- | |
lon1d: numpy.array | |
Array of longitude points [degrees] of shape (M,) | |
lat1d: numpy.array | |
Array of latitude points [degrees] of shape (M,) | |
radius: float, optional | |
Radius of the planet [metres] (currently assumed spherical) | |
Returns | |
------- | |
Array of grid cell areas [metres**2] of shape (M, N). | |
""" | |
lon_bounds_radian = np.deg2rad(_guess_bounds(lon1d)) | |
lat_bounds_radian = np.deg2rad(_guess_bounds(lat1d)) | |
area = _quadrant_area(lat_bounds_radian, lon_bounds_radian, radius) | |
return area | |
def calc_spatial_mean( | |
xr_da, lon_name="longitude", lat_name="latitude", radius=EARTH_RADIUS | |
): | |
""" | |
Calculate spatial mean of xarray.DataArray with grid cell weighting. | |
Parameters | |
---------- | |
xr_da: xarray.DataArray | |
Data to average | |
lon_name: str, optional | |
Name of x-coordinate | |
lat_name: str, optional | |
Name of y-coordinate | |
radius: float | |
Radius of the planet [metres], currently assumed spherical (not important anyway) | |
Returns | |
------- | |
Spatially averaged xarray.DataArray. | |
""" | |
lon = xr_da[lon_name].values | |
lat = xr_da[lat_name].values | |
area_weights = grid_cell_areas(lon, lat, radius=radius) | |
aw_factor = area_weights / area_weights.max() | |
return (xr_da * aw_factor).mean(dim=[lon_name, lat_name]) | |
def calc_spatial_integral( | |
xr_da, lon_name="longitude", lat_name="latitude", radius=EARTH_RADIUS | |
): | |
""" | |
Calculate spatial integral of xarray.DataArray with grid cell weighting. | |
Parameters | |
---------- | |
xr_da: xarray.DataArray | |
Data to average | |
lon_name: str, optional | |
Name of x-coordinate | |
lat_name: str, optional | |
Name of y-coordinate | |
radius: float | |
Radius of the planet [metres], currently assumed spherical (not important anyway) | |
Returns | |
------- | |
Spatially averaged xarray.DataArray. | |
""" | |
lon = xr_da[lon_name].values | |
lat = xr_da[lat_name].values | |
area_weights = grid_cell_areas(lon, lat, radius=radius) | |
return (xr_da * area_weights).sum(dim=[lon_name, lat_name]) |
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A function to calculate meridional averages of iris cubes: