Note
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Geographical Gradient (Spherical Harmonics)¶
The spherical-harmonic gradient returns zonal and meridional derivatives of
a scalar field. This example calculates the gradient of zonal wind with
easyclimate.spec.calc_gradient
and compares it with
easyclimate.spec.calc_gradient_rs.
import cartopy.crs as ccrs
import xarray as xr
import matplotlib.pyplot as plt
import easyclimate as ecl
Open the tutorial zonal and meridional wind components, combine them into one dataset, and select one 500 hPa time slice for the calculation.
u_data = ecl.open_tutorial_dataset("uwnd_2022_day5").uwnd
v_data = ecl.open_tutorial_dataset("vwnd_2022_day5").vwnd
uvdata = xr.Dataset()
uvdata["uwnd"] = u_data
uvdata["vwnd"] = v_data
uvdata_500_202201 = uvdata.sel(level=500).isel(time = 3)
uvdata_500_202201
Prepare a scientific-notation formatter for the colorbars. Many spectral wind diagnostics have small physical units, so this keeps the labels readable.
import matplotlib.ticker as ticker
formatter = ticker.ScalarFormatter(useMathText=True, useOffset=True)
formatter.set_scientific(True)
formatter.set_powerlimits((0, 0))
The returned dataset contains zonal_gradient and meridional_gradient on the input grid.
uvgrd_fp = ecl.spec.calc_gradient(
data_input=uvdata_500_202201["uwnd"],
)
uvgrd_rs = ecl.spec.calc_gradient_rs(
data_input=uvdata_500_202201["uwnd"],
)
The first figure maps the zonal and meridional gradients from the Fortran-backed calculation.
fig, ax = plt.subplots(
2, 1,
figsize = (10, 10),
subplot_kw={"projection": ccrs.Mercator(central_longitude=180)}
)
for axi in ax.flat:
axi.coastlines()
axi.gridlines(crs=ccrs.PlateCarree(), draw_labels=["bottom", "left"], alpha = 0)
axi = ax[0]
uvgrd_fp["zonal_gradient"].sortby("lat").sel(lat=slice(20, 80)).plot.contourf(
levels=21,
ax = axi,
cbar_kwargs = {'location': 'bottom', 'format': formatter, 'pad': 0.1},
transform = ccrs.PlateCarree(),
)
axi = ax[1]
uvgrd_fp["meridional_gradient"].sortby("lat").sel(lat=slice(20, 80)).plot.contourf(
levels=21,
ax = axi,
cbar_kwargs = {'location': 'bottom', 'format': formatter, 'pad': 0.1},
transform = ccrs.PlateCarree(),
)

<cartopy.mpl.contour.GeoContourSet object at 0x79c56d151220>
The final figure compares each gradient component from the two backends and plots the component-wise differences.
fig, ax = plt.subplots(2, 3, figsize = (15, 10))
uvgrd_fp["zonal_gradient"].sortby("lat").sel(lat=slice(20, 80)).plot.contourf(
levels=21,
ax = ax[0, 0],
cbar_kwargs = {'location': 'bottom'},
)
ax[0, 0].set_title("Fortran")
uvgrd_rs["zonal_gradient"].sortby("lat").sel(lat=slice(20, 80)).plot.contourf(
levels=21,
ax = ax[0, 1],
cbar_kwargs = {'location': 'bottom'},
)
ax[0, 1].set_title("Rust")
(uvgrd_fp["zonal_gradient"] - uvgrd_rs["zonal_gradient"]).sortby("lat").sel(lat=slice(20, 80)).plot(
ax = ax[0, 2],
cbar_kwargs = {'location': 'bottom'},
)
ax[0, 2].set_title("Diff: Fortran - Rust")
uvgrd_fp["meridional_gradient"].sortby("lat").sel(lat=slice(20, 80)).plot.contourf(
levels=21,
ax = ax[1, 0],
cbar_kwargs = {'location': 'bottom'},
)
ax[1, 0].set_title("Fortran")
uvgrd_rs["meridional_gradient"].sortby("lat").sel(lat=slice(20, 80)).plot.contourf(
levels=21,
ax = ax[1, 1],
cbar_kwargs = {'location': 'bottom'},
)
ax[1, 1].set_title("Rust")
(uvgrd_fp["meridional_gradient"] - uvgrd_rs["meridional_gradient"]).sortby("lat").sel(lat=slice(20, 80)).plot(
ax = ax[1, 2],
cbar_kwargs = {'location': 'bottom'},
)
ax[1, 2].set_title("Diff: Fortran - Rust")

Text(0.5, 1.0, 'Diff: Fortran - Rust')
Total running time of the script: (0 minutes 10.272 seconds)