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script_15.py
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script_15.py
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#-----------------------------------------------------------------------------------------------------------
# INPE / CPTEC Training: NWP Data Processing With Python - Script 15: Wind Vectors
# Author: Diego Souza
#-----------------------------------------------------------------------------------------------------------
import pygrib # Provides a high-level interface to the ECWMF ECCODES C library for reading GRIB files
import matplotlib.pyplot as plt # Plotting library
import cartopy, cartopy.crs as ccrs # Plot maps
import cartopy.io.shapereader as shpreader # Import shapefiles
import numpy as np # Scientific computing with Python
import matplotlib # Comprehensive library for creating static, animated, and interactive visualizations in Python
#-----------------------------------------------------------------------------------------------------------
# Select the extent [min. lon, min. lat, max. lon, max. lat]
extent = [-93.0, -60.00, -25.00, 18.00]
# Open the GRIB file
grib = pygrib.open("gfs.t00z.pgrb2full.0p50.f000")
#-----------------------------------------------------------------------------------------------------------
# Select the variable
ucomp = grib.select(name='U component of wind', typeOfLevel = 'isobaricInhPa', level = 925)[0]
# Get information from the file
init = str(ucomp.analDate) # Init date / time
run = str(ucomp.hour).zfill(2) # Run
ftime = str(ucomp.forecastTime) # Forecast hour
valid = str(ucomp.validDate) # Valid date / time
print('Init: ' + init + ' UTC')
print('Run: ' + run + 'Z')
print('Forecast: +' + ftime)
print('Valid: ' + valid + ' UTC')
# Read the data for a specific region
ucomp, lats, lons = ucomp.data(lat1=extent[1],lat2=extent[3],lon1=extent[0]+360,lon2=extent[2]+360)
#-----------------------------------------------------------------------------------------------------------
# Select the variable
vcomp = grib.select(name='V component of wind', typeOfLevel = 'isobaricInhPa', level = 925)[0]
# Read the data for a specific region
vcomp = vcomp.data(lat1=extent[1],lat2=extent[3],lon1=extent[0]+360,lon2=extent[2]+360)[0]
#-----------------------------------------------------------------------------------------------------------
# Calculate the wind speed
ws = np.sqrt(ucomp**2 + vcomp**2)
#-----------------------------------------------------------------------------------------------------------
# Choose the plot size (width x height, in inches)
plt.figure(figsize=(8,8))
# Use the Cilindrical Equidistant projection in cartopy
ax = plt.axes(projection=ccrs.PlateCarree())
# Define the image extent
img_extent = [extent[0], extent[2], extent[1], extent[3]]
ax.set_extent([extent[0], extent[2], extent[1], extent[3]], ccrs.PlateCarree())
# Add a shapefile
# https://geoftp.ibge.gov.br/organizacao_do_territorio/malhas_territoriais/malhas_municipais/municipio_2019/Brasil/BR/br_unidades_da_federacao.zip
shapefile = list(shpreader.Reader('BR_UF_2019.shp').geometries())
ax.add_geometries(shapefile, ccrs.PlateCarree(), edgecolor='gray',facecolor='none', linewidth=0.3)
# Add coastlines, borders and gridlines
ax.coastlines(resolution='10m', color='black', linewidth=0.8)
ax.add_feature(cartopy.feature.BORDERS, edgecolor='black', linewidth=0.5)
gl = ax.gridlines(crs=ccrs.PlateCarree(), color='gray', alpha=1.0, linestyle='--', linewidth=0.25, xlocs=np.arange(-180, 180, 5), ylocs=np.arange(-90, 90, 5), draw_labels=True)
gl.top_labels = False
gl.right_labels = False
# Define de contour interval
data_min = 0
data_max = 60
interval = 5
levels = np.arange(data_min,data_max,interval)
# Create a custom color palette
colors = ["#e7f2f4", "#ceeaee", "#b6e2e8", "#abdcff", "#a4d685", "#9cd04e", "#abcf2a", "#c9d21b", "#e8d50c", "#ffd100", "#ffba00", "#ffa200"]
cmap = matplotlib.colors.ListedColormap(colors)
cmap.set_over('#ff8c00')
cmap.set_under('#fffafa')
# Plot the contours
img1 = ax.contourf(lons, lats, ws, cmap=cmap, levels=levels, extend='both')
img2 = ax.contour(lons, lats, ws, colors='white', linewidths=0.3, levels=levels)
ax.clabel(img2, inline=1, inline_spacing=0, fontsize='10',fmt = '%1.0f', colors= 'black')
# Plot the quiver
img3 = ax.quiver(lons[::4,::4], lats[::4,::4], ucomp[::4,::4], vcomp[::4,::4])
#img3 = ax.quiver(lons[::4,::4], lats[::4,::4], ucomp[::4,::4], vcomp[::4,::4], ws[::4,::4], cmap='jet')#, width = 0.022, scale = 1 / 0.15, color=ws, cmap='jet')
qk = ax.quiverkey(img3, 0.50, 0.89, 20, '20 kt', labelpos='E', coordinates='figure')
# Add a colorbar
plt.colorbar(img1, label='Wind Speed (kt)', orientation='vertical', pad=0.05, fraction=0.05)
# Add a title
plt.title('GFS: Wind Speed (kt) & Direction (925 hPa)' , fontweight='bold', fontsize=10, loc='left')
plt.title('Valid: ' + valid, fontsize=10, loc='right')
#-----------------------------------------------------------------------------------------------------------
# Save the image
plt.savefig('image_15.png', bbox_inches='tight', pad_inches=0, dpi=100)
# Show the image
plt.show()