{ "cells": [ { "cell_type": "code", "execution_count": null, "metadata": {}, "outputs": [], "source": [ "from __future__ import print_function\n", "\n", "# This jupyter notebook command inserts matplotlib graphics in \n", "# to the workbook\n", "%matplotlib inline\n", "\n", "# Modify these to point to your own files\n", "WRF_DIRECTORY = \"/Users/ladwig/Documents/wrf_files/wrf_vortex_multi/moving_nest\"\n", "\n", "WRF_FILES = [\"wrfout_d02_2005-08-28_00:00:00\",\n", " \"wrfout_d02_2005-08-28_12:00:00\",\n", " \"wrfout_d02_2005-08-29_00:00:00\"]\n", "\n", "\n", "# Do not modify the code below this line\n", "#------------------------------------------------------\n", "# Turn off annoying warnings\n", "import warnings\n", "warnings.filterwarnings('ignore')\n", "\n", "# Make sure the environment is good\n", "import numpy\n", "import cartopy\n", "import matplotlib\n", "from netCDF4 import Dataset\n", "from xarray import DataArray\n", "from wrf import (getvar, interplevel, vertcross, \n", " vinterp, ALL_TIMES)\n", "import os\n", "\n", "_WRF_FILES = [os.path.abspath(os.path.expanduser(\n", " os.path.join(WRF_DIRECTORY, f))) for f in WRF_FILES]\n", "\n", "# Check that the WRF files exist\n", "try:\n", " for f in _WRF_FILES:\n", " if not os.path.exists(f):\n", " raise ValueError(\"{} does not exist. \"\n", " \"Check for typos or incorrect directory.\".format(f))\n", "except ValueError:\n", " # If the directory ended up in the zip file, then \n", " # another 'wrf_tutorial_data' directory might be \n", " # used.\n", " WRF_DIRECTORY = os.path.join(WRF_DIRECTORY, \"wrf_tutorial_data\")\n", " _WRF_FILES = [os.path.abspath(os.path.expanduser(\n", " os.path.join(WRF_DIRECTORY, f))) for f in WRF_FILES]\n", " for f in _WRF_FILES:\n", " if not os.path.exists(f):\n", " raise\n", "\n", " \n", "# Create functions so that the WRF files only need\n", "# to be specified using the WRF_FILES global above\n", "def single_wrf_file():\n", " global _WRF_FILES\n", " return _WRF_FILES[0]\n", "\n", "def multiple_wrf_files():\n", " global _WRF_FILES\n", " return _WRF_FILES\n", "\n", "def save_fig(diagname):\n", " f = single_wrf_file()\n", " if f.find(\"_d01_\") > 0:\n", " fout = \"{}.png\".format(os.path.join(os.path.abspath(\".\"), \"d01\", diagname))\n", " else:\n", " fout = \"{}.png\".format(os.path.join(os.path.abspath(\".\"), \"d02\", diagname))\n", " \n", " matplotlib.pyplot.savefig(fout)\n", " \n", "\n", "print(\"All tests passed!\")" ] }, { "cell_type": "code", "execution_count": null, "metadata": {}, "outputs": [], "source": [ "def get_kwargs(diagname):\n", " kwargs = {}\n", " if diagname == \"ctt\":\n", " kwargs = {\"fill_nocloud\" : True}\n", " \n", " return kwargs" ] }, { "cell_type": "code", "execution_count": null, "metadata": {}, "outputs": [], "source": [ "def contour_levels(diagname, diag, numlevels=15):\n", " levels = numlevels\n", " extend = \"neither\"\n", " if diagname == \"ter\":\n", " levels = numpy.arange(10.,4000.,250.)\n", " elif diagname == \"avo\":\n", " levels = numpy.arange(10.,75.,5.)\n", " extend=\"max\"\n", " elif diagname == \"eth\":\n", " levels = numpy.arange(270.,400.,10.)\n", " elif diagname == \"cape_2d\":\n", " levels = numpy.arange(200.,4000.,250.)\n", " extend = \"max\"\n", " elif diagname == \"cape_3d\":\n", " levels = numpy.arange(200.,4000.,250.)\n", " extend = \"max\"\n", " elif diagname == \"ctt\":\n", " # Note: The MP scheme doesn't produce cloud water so this\n", " # is just surface temperature\n", " levels = numpy.arange(-100, 20., 5.0)\n", " extend = \"both\"\n", " elif diagname == \"dbz\":\n", " #pass\n", " levels = numpy.arange(15.,75.,5.)\n", " extend = \"max\"\n", " elif diagname == \"mdbz\":\n", " levels = numpy.arange(15.,75.,5.)\n", " extend = \"max\"\n", " elif diagname == \"geopt\":\n", " pass\n", " elif diagname == \"helicity\":\n", " levels = numpy.arange(100,500,25)\n", " extend=\"max\"\n", " elif diagname == \"lat\":\n", " pass\n", " elif diagname == \"lon\":\n", " pass\n", " elif diagname == \"omg\":\n", " pass\n", " elif diagname == \"p\":\n", " levels = numpy.arange(95000.,103000.,250.)\n", " extend = \"min\"\n", " elif diagname == \"pressure\":\n", " levels = numpy.arange(950.,1030.,2.5)\n", " extend = \"min\"\n", " elif diagname == \"pvo\":\n", " levels = numpy.arange(.5,5.,.25)\n", " elif diagname == \"pw\":\n", " #pass\n", " levels = numpy.arange(0.1,100,10)\n", " elif diagname == \"rh2\":\n", " levels = numpy.arange(50,101,5)\n", " elif diagname == \"rh\":\n", " levels = numpy.arange(50.,101.,5)\n", " elif diagname == \"slp\":\n", " levels = numpy.arange(950.,1030.,2.5)\n", " extend = \"min\"\n", " elif diagname == \"td2\":\n", " levels = numpy.arange(10,40,5)\n", " extend = \"max\"\n", " elif diagname == \"td\":\n", " levels = numpy.arange(10,40,5)\n", " extend = \"max\"\n", " elif diagname == \"tc\":\n", " levels = numpy.arange(10,40,5)\n", " extend = \"max\"\n", " elif diagname == \"theta\":\n", " levels = numpy.arange(270.,350.,2.5)\n", " elif diagname == \"tk\":\n", " levels = numpy.arange(270.,350.,5.)\n", " elif diagname == \"tv\":\n", " levels = numpy.arange(270.,350.,5.)\n", " #levels = numpy.arange(10,40,5)\n", " elif diagname == \"twb\":\n", " levels = numpy.arange(270.,350.,5.) \n", " elif diagname == \"updraft_helicity\":\n", " pass\n", " #levels = numpy.arange(1,100,5)\n", " elif diagname == \"ua\":\n", " levels = numpy.arange(-40,40,5)\n", " extend = \"both\"\n", " elif diagname == \"va\":\n", " levels = numpy.arange(-40,40,5)\n", " extend = \"both\"\n", " elif diagname == \"wa\":\n", " pass\n", " #levels = numpy.arange(0.1,40,5)\n", " elif diagname == \"uvmet10\":\n", " levels = numpy.arange(-40,40,5)\n", " extend = \"both\"\n", " elif diagname == \"uvmet\":\n", " levels = numpy.arange(-40,40,5)\n", " extend = \"both\"\n", " elif diagname == \"z\":\n", " levels = numpy.arange(0,200,10)\n", " extend=\"max\"\n", " elif diagname == \"cfrac\":\n", " levels = numpy.arange(0.0,1.1,.2)\n", " elif diagname == \"wspd_wdir\":\n", " levels = numpy.arange(-40,40,5)\n", " extend = \"both\"\n", " elif diagname == \"wspd_wdir10\":\n", " levels = numpy.arange(-40,40,5)\n", " extend = \"both\"\n", " elif diagname == \"uvmet_wspd_wdir\":\n", " levels = numpy.arange(-40,40,5)\n", " extend = \"both\"\n", " elif diagname == \"uvmet10_wspd_wdir\":\n", " levels = numpy.arange(-40,40,5)\n", " extend = \"both\"\n", " elif diagname ==\"cape2d_only\":\n", " levels = numpy.arange(200.,4000.,250.)\n", " extend = \"max\"\n", " elif diagname ==\"cin2d_only\": \n", " levels = numpy.arange(10.,200.,10.)\n", " extend = \"max\"\n", " elif diagname ==\"lcl\":\n", " levels = numpy.arange(50.,2000.,50.)\n", " extend = \"max\"\n", " elif diagname ==\"lfc\": \n", " levels = numpy.arange(100.,5000.,100.)\n", " extend = \"max\"\n", " elif diagname ==\"cape3d_only\": \n", " levels = numpy.arange(200.,4000.,250.)\n", " extend = \"max\"\n", " elif diagname ==\"cin3d_only\": \n", " levels = levels = numpy.arange(10.,200.,10.)\n", " extend = \"max\"\n", " elif diagname ==\"uvmet_wspd\": \n", " levels = numpy.arange(-40,40,5)\n", " extend = \"both\"\n", " elif diagname ==\"uvmet_wdir\": \n", " levels = numpy.arange(0,370,10)\n", " elif diagname ==\"uvmet10_wspd\": \n", " levels = numpy.arange(-40,40,5)\n", " extend = \"both\"\n", " elif diagname ==\"uvmet10_wdir\": \n", " levels = numpy.arange(0,370,10)\n", " elif diagname ==\"wspd\": \n", " levels = numpy.arange(-40,40,5)\n", " extend = \"both\"\n", " elif diagname ==\"wdir\": \n", " levels = numpy.arange(0,370,10)\n", " elif diagname ==\"wspd10\": \n", " levels = numpy.arange(-40,40,5)\n", " extend = \"both\"\n", " elif diagname ==\"wdir10\": \n", " levels = numpy.arange(0,370,10)\n", " elif diagname ==\"low_cfrac\":\n", " levels = numpy.arange(0.0,1.1,.2)\n", " elif diagname ==\"mid_cfrac\": \n", " levels = numpy.arange(0.0,1.1,.2)\n", " elif diagname ==\"high_cfrac\":\n", " levels = numpy.arange(0.0,1.1,.2)\n", " \n", " return levels, extend" ] }, { "cell_type": "code", "execution_count": null, "metadata": { "scrolled": false }, "outputs": [], "source": [ "import numpy\n", "from matplotlib import pyplot\n", "from matplotlib.cm import get_cmap\n", "from cartopy import crs\n", "from cartopy.feature import NaturalEarthFeature\n", "from netCDF4 import Dataset\n", "from wrf import getvar, to_np, get_cartopy, latlon_coords, cartopy_xlim, cartopy_ylim, Constants\n", "\n", "file_path = single_wrf_file()\n", "wrf_file = Dataset(file_path)\n", "\n", "for diagname in (\"ter\",\"avo\", \"eth\", \"cape_2d\", \"cape_3d\", \"ctt\", \"dbz\", \"mdbz\", \n", " \"geopt\", \"helicity\", \"lat\", \"lon\", \"omg\", \"p\", \"pressure\", \n", " \"pvo\", \"pw\", \"rh2\", \"rh\", \"slp\", \"td2\", \"td\", \"tc\",\n", " \"theta\", \"tk\", \"tv\", \"twb\", \"updraft_helicity\", \"ua\", \"va\", \n", " \"wa\", \"uvmet10\", \"uvmet\", \"z\", \"wspd_wdir\", \"wspd_wdir10\",\n", " \"uvmet_wspd_wdir\", \"uvmet10_wspd_wdir\", \"cfrac\",\n", " \"cape2d_only\",\"cin2d_only\", \"lcl\", \"lfc\", \"cape3d_only\", \"cin3d_only\",\"uvmet_wspd\", \n", " \"uvmet_wdir\",\"uvmet10_wspd\", \"uvmet10_wdir\",\"wspd\", \"wdir\", \"wspd10\", \"wdir10\",\n", " \"low_cfrac\", \"mid_cfrac\", \"high_cfrac\"):\n", " \n", " # Get the terrain height\n", " print(diagname)\n", " kwargs = get_kwargs(diagname)\n", " diag = getvar(wrf_file, diagname, timeidx=3, **kwargs)\n", "\n", " if diag.ndim == 3:\n", " diag = diag[0,:]\n", " elif diag.ndim == 4:\n", " diag = diag[0,0,:]\n", "\n", " # Get the cartopy object and the lat,lon coords\n", " cart_proj = get_cartopy(diag)\n", " lats, lons = latlon_coords(diag)\n", " \n", "\n", " # Create a figure and get the GetAxes object\n", " fig = pyplot.figure(figsize=(10, 7.5))\n", " ax = pyplot.axes(projection=cart_proj)\n", "\n", " # Download and add the states and coastlines\n", " # See the cartopy documentation for more on this.\n", " states = NaturalEarthFeature(category='cultural', \n", " scale='50m', \n", " facecolor='none',\n", " name='admin_1_states_provinces_shp')\n", "\n", " ax.add_feature(states, linewidth=.5, edgecolor='black', zorder=3)\n", " ax.coastlines('50m', linewidth=.8, color='black', zorder=4)\n", "\n", " # Set the contour levels\n", " levels, extend = contour_levels(diagname, diag, numlevels=15)\n", "\n", " # Make the contour lines and fill them.\n", " pyplot.contour(to_np(lons), to_np(lats), \n", " to_np(diag), levels=levels, \n", " colors=\"black\",\n", " transform=crs.PlateCarree())\n", " pyplot.contourf(to_np(lons), to_np(lats), \n", " to_np(diag), levels=levels,\n", " transform=crs.PlateCarree(),\n", " extend=extend,\n", " cmap=get_cmap(\"jet\"))\n", "\n", " ax.set_xlim(cartopy_xlim(diag))\n", " ax.set_ylim(cartopy_ylim(diag))\n", " \n", " # Add a color bar. The shrink often needs to be set \n", " # by trial and error.\n", " cb = pyplot.colorbar(ax=ax, shrink=.99)\n", " \n", " pyplot.title(diagname)\n", " \n", " # Uncomment this to build the sample images\n", " #save_fig(diagname)\n", " \n", " pyplot.show()\n", "\n", "\n" ] } ], "metadata": { "kernelspec": { "display_name": "Python 3", "language": "python", "name": "python3" }, "language_info": { "codemirror_mode": { "name": "ipython", "version": 3 }, "file_extension": ".py", "mimetype": "text/x-python", "name": "python", "nbconvert_exporter": "python", "pygments_lexer": "ipython3", "version": "3.6.7" } }, "nbformat": 4, "nbformat_minor": 2 }