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October 14, 2015 15:11
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Simple WRF analysis/plotting examples
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| { | |
| "cells": [ | |
| { | |
| "cell_type": "markdown", | |
| "metadata": {}, | |
| "source": [ | |
| "This is a simple example for plotting WRF output using several standard Python libraries:\n", | |
| "\n", | |
| "1. [xray](http://xray.readthedocs.org/en/stable/) - netCDF reading and data manipulation\n", | |
| "2. [matplotlib](http://matplotlib.org/) - Python basic plotting library\n", | |
| "3. [cartopy](http://scitools.org.uk/cartopy/docs/latest/index.html) - Geographic plotting library build on matplotlib\n", | |
| "\n", | |
| "If you're already using Anaconda, then the easiest way to install these will be to simply go to your command line and execute:\n", | |
| "\n", | |
| "```bash\n", | |
| "conda install xray matplotlib cartopy\n", | |
| "```\n", | |
| "\n", | |
| "Alternatively, you could use `pip` or install them from source, but that's not recommended. Other libraries to consider would be [iris](http://scitools.org.uk/iris/docs/latest/index.html) for reading in/handling netCDF data, or [matplotlib basemap](http://matplotlib.org/basemap/) for geographic plotting." | |
| ] | |
| }, | |
| { | |
| "cell_type": "markdown", | |
| "metadata": {}, | |
| "source": [ | |
| "### Reading in data\n", | |
| "\n", | |
| "Using `xray`, it's trivial to read in a netCDF dataset. I've attached a timeslice of output from a simulation of a mid-latitude squall line in the file [squall_slice.nc]() for this purpose." | |
| ] | |
| }, | |
| { | |
| "cell_type": "code", | |
| "execution_count": 1, | |
| "metadata": { | |
| "collapsed": true | |
| }, | |
| "outputs": [], | |
| "source": [ | |
| "import xray\n", | |
| "\n", | |
| "dataset = xray.open_dataset(\"squall_slice.nc\")" | |
| ] | |
| }, | |
| { | |
| "cell_type": "markdown", | |
| "metadata": {}, | |
| "source": [ | |
| "Normally, you'd use `ncdump -h squall_slice.nc` from the command line to inspect this file, but we can do something equivalent using xray." | |
| ] | |
| }, | |
| { | |
| "cell_type": "code", | |
| "execution_count": 2, | |
| "metadata": { | |
| "collapsed": false, | |
| "scrolled": false | |
| }, | |
| "outputs": [ | |
| { | |
| "name": "stdout", | |
| "output_type": "stream", | |
| "text": [ | |
| "<xray.Dataset>\n", | |
| "Dimensions: (Time: 1, bottom_top: 80, bottom_top_stag: 81, south_north: 100, west_east: 500)\n", | |
| "Coordinates:\n", | |
| " XLAT (Time, south_north, west_east) float32 0.0 0.0 0.0 0.0 ...\n", | |
| " XLONG (Time, south_north, west_east) float32 0.0 0.0 0.0 0.0 ...\n", | |
| " * Time (Time) int64 0\n", | |
| " * bottom_top (bottom_top) int64 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 ...\n", | |
| " * bottom_top_stag (bottom_top_stag) int64 0 1 2 3 4 5 6 7 8 9 10 11 12 13 ...\n", | |
| " * south_north (south_north) int64 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 ...\n", | |
| " * west_east (west_east) int64 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 ...\n", | |
| "Data variables:\n", | |
| " P (Time, bottom_top, south_north, west_east) float32 11.1484 ...\n", | |
| " PB (Time, bottom_top, south_north, west_east) float32 96225.7 ...\n", | |
| " PH (Time, bottom_top_stag, south_north, west_east) float32 0.0 ...\n", | |
| " PHB (Time, bottom_top_stag, south_north, west_east) float32 0.0 ...\n", | |
| " PSFC (Time, south_north, west_east) float32 0.0 0.0 0.0 0.0 ...\n", | |
| " QCLOUD (Time, bottom_top, south_north, west_east) float32 0.0 ...\n", | |
| " QRAIN (Time, bottom_top, south_north, west_east) float32 0.0 ...\n", | |
| " QVAPOR (Time, bottom_top, south_north, west_east) float32 0.0196612 ...\n", | |
| " T (Time, bottom_top, south_north, west_east) float32 1.60981 ...\n", | |
| " T2 (Time, south_north, west_east) float32 0.0 0.0 0.0 0.0 ...\n", | |
| "Attributes:\n", | |
| " TITLE: OUTPUT FROM WRF V3.6 MODEL\n", | |
| " START_DATE: 2011-04-25_18:00:00\n", | |
| " SIMULATION_START_DATE: 2011-04-25_18:00:00\n", | |
| " WEST-EAST_GRID_DIMENSION: 501\n", | |
| " SOUTH-NORTH_GRID_DIMENSION: 101\n", | |
| " BOTTOM-TOP_GRID_DIMENSION: 81\n", | |
| " DX: 1000.0\n", | |
| " DY: 1000.0\n", | |
| " STOCH_FORCE_OPT: 0\n", | |
| " GRIDTYPE: C\n", | |
| " DIFF_OPT: 2\n", | |
| " KM_OPT: 2\n", | |
| " DAMP_OPT: 0\n", | |
| " DAMPCOEF: 0.003\n", | |
| " KHDIF: 0.0\n", | |
| " KVDIF: 0.0\n", | |
| " MP_PHYSICS: 9\n", | |
| " RA_LW_PHYSICS: 0\n", | |
| " RA_SW_PHYSICS: 0\n", | |
| " SF_SFCLAY_PHYSICS: 0\n", | |
| " SF_SURFACE_PHYSICS: 0\n", | |
| " BL_PBL_PHYSICS: 0\n", | |
| " CU_PHYSICS: 0\n", | |
| " SF_LAKE_PHYSICS: 0\n", | |
| " SURFACE_INPUT_SOURCE: 1\n", | |
| " SST_UPDATE: 0\n", | |
| " GRID_FDDA: 0\n", | |
| " GFDDA_INTERVAL_M: 0\n", | |
| " GFDDA_END_H: 0\n", | |
| " GRID_SFDDA: 0\n", | |
| " SGFDDA_INTERVAL_M: 0\n", | |
| " SGFDDA_END_H: 0\n", | |
| " HYPSOMETRIC_OPT: 1\n", | |
| " SF_URBAN_PHYSICS: 0\n", | |
| " SHCU_PHYSICS: 0\n", | |
| " MFSHCONV: 0\n", | |
| " FEEDBACK: 1\n", | |
| " SMOOTH_OPTION: 2\n", | |
| " SWRAD_SCAT: 1.0\n", | |
| " W_DAMPING: 0\n", | |
| " DT: 5.0\n", | |
| " RADT: 0.0\n", | |
| " BLDT: 0.0\n", | |
| " CUDT: 0.0\n", | |
| " AER_OPT: 0\n", | |
| " SWINT_OPT: 0\n", | |
| " AER_TYPE: 1\n", | |
| " AER_AOD550_OPT: 1\n", | |
| " AER_ANGEXP_OPT: 1\n", | |
| " AER_SSA_OPT: 1\n", | |
| " AER_ASY_OPT: 1\n", | |
| " AER_AOD550_VAL: 0.12\n", | |
| " AER_ANGEXP_VAL: 1.3\n", | |
| " AER_SSA_VAL: 1.4013e-45\n", | |
| " AER_ASY_VAL: 1.4013e-45\n", | |
| " MOIST_ADV_OPT: 1\n", | |
| " SCALAR_ADV_OPT: 1\n", | |
| " TKE_ADV_OPT: 1\n", | |
| " DIFF_6TH_OPT: 0\n", | |
| " DIFF_6TH_FACTOR: 0.12\n", | |
| " OBS_NUDGE_OPT: 0\n", | |
| " BUCKET_MM: -1.0\n", | |
| " BUCKET_J: -1.0\n", | |
| " PREC_ACC_DT: 0.0\n", | |
| " SF_OCEAN_PHYSICS: 0\n", | |
| " ISFTCFLX: 0\n", | |
| " ISHALLOW: 0\n", | |
| " ISFFLX: 0\n", | |
| " ICLOUD: 0\n", | |
| " ICLOUD_CU: 0\n", | |
| " TRACER_PBLMIX: 1\n", | |
| " SCALAR_PBLMIX: 0\n", | |
| " GRAV_SETTLING: 0\n", | |
| " DFI_OPT: 0\n", | |
| " WEST-EAST_PATCH_START_UNSTAG: 1\n", | |
| " WEST-EAST_PATCH_END_UNSTAG: 500\n", | |
| " WEST-EAST_PATCH_START_STAG: 1\n", | |
| " WEST-EAST_PATCH_END_STAG: 501\n", | |
| " SOUTH-NORTH_PATCH_START_UNSTAG: 1\n", | |
| " SOUTH-NORTH_PATCH_END_UNSTAG: 100\n", | |
| " SOUTH-NORTH_PATCH_START_STAG: 1\n", | |
| " SOUTH-NORTH_PATCH_END_STAG: 101\n", | |
| " BOTTOM-TOP_PATCH_START_UNSTAG: 1\n", | |
| " BOTTOM-TOP_PATCH_END_UNSTAG: 80\n", | |
| " BOTTOM-TOP_PATCH_START_STAG: 1\n", | |
| " BOTTOM-TOP_PATCH_END_STAG: 81\n", | |
| " GRID_ID: 1\n", | |
| " PARENT_ID: 0\n", | |
| " I_PARENT_START: 1\n", | |
| " J_PARENT_START: 1\n", | |
| " PARENT_GRID_RATIO: 1\n", | |
| " CEN_LAT: 0.0\n", | |
| " CEN_LON: 0.0\n", | |
| " TRUELAT1: 0.0\n", | |
| " TRUELAT2: 0.0\n", | |
| " MOAD_CEN_LAT: 0.0\n", | |
| " STAND_LON: 0.0\n", | |
| " POLE_LAT: 0.0\n", | |
| " POLE_LON: 0.0\n", | |
| " GMT: 0.0\n", | |
| " JULYR: 0\n", | |
| " JULDAY: 1\n", | |
| " MAP_PROJ: 0\n", | |
| " MAP_PROJ_CHAR: Cartesian\n", | |
| " MMINLU: \n", | |
| " NUM_LAND_CAT: 24\n", | |
| " ISWATER: 0\n", | |
| " ISLAKE: 0\n", | |
| " ISICE: 0\n", | |
| " ISURBAN: 0\n", | |
| " ISOILWATER: 0\n", | |
| " history: Wed Oct 14 10:17:31 2015: ncks -d Time,0 -v PH,PHB,T,P,PB,PSFC,T2,QRAIN,QVAPOR,QCLOUD,XLAT,XLONG squall3d_03z.nc -o squall_slice.nc\n", | |
| " NCO: 4.4.7\n" | |
| ] | |
| } | |
| ], | |
| "source": [ | |
| "print(dataset)" | |
| ] | |
| }, | |
| { | |
| "cell_type": "markdown", | |
| "metadata": {}, | |
| "source": [ | |
| "We can look into more detail at a given field, too, to see what metadata is attached to it. Note that the default container that `xray` provides, the **Dataset**, implements the standard dictionary interface, so it's easy to grab data fields." | |
| ] | |
| }, | |
| { | |
| "cell_type": "code", | |
| "execution_count": 3, | |
| "metadata": { | |
| "collapsed": false | |
| }, | |
| "outputs": [ | |
| { | |
| "name": "stdout", | |
| "output_type": "stream", | |
| "text": [ | |
| "<xray.DataArray 'QRAIN' (Time: 1, bottom_top: 80, south_north: 100, west_east: 500)>\n", | |
| "[4000000 values with dtype=float32]\n", | |
| "Coordinates:\n", | |
| " XLONG (Time, south_north, west_east) float32 0.0 0.0 0.0 0.0 0.0 ...\n", | |
| " * bottom_top (bottom_top) int64 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 ...\n", | |
| " * Time (Time) int64 0\n", | |
| " * south_north (south_north) int64 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 ...\n", | |
| " XLAT (Time, south_north, west_east) float32 0.0 0.0 0.0 0.0 0.0 ...\n", | |
| " * west_east (west_east) int64 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 ...\n", | |
| "Attributes:\n", | |
| " FieldType: 104\n", | |
| " MemoryOrder: XYZ\n", | |
| " description: Rain water mixing ratio\n", | |
| " units: kg kg-1\n", | |
| " stagger: \n" | |
| ] | |
| } | |
| ], | |
| "source": [ | |
| "rain = dataset['QRAIN']\n", | |
| "print(rain)" | |
| ] | |
| }, | |
| { | |
| "cell_type": "markdown", | |
| "metadata": {}, | |
| "source": [ | |
| "To illustrate simple data manipulation, let's compute total rain amount for each model column in the `y` dimension, and plot against `x`. This will give us an idea of where the squall line is located in the model domain. \n", | |
| "\n", | |
| "Rather than use giant loops over all the model dimensions, we'll use the convenience tools exposed by `xray`. See [here](http://xray.readthedocs.org/en/stable/data-structures.html?highlight=pipe) for more details." | |
| ] | |
| }, | |
| { | |
| "cell_type": "code", | |
| "execution_count": 23, | |
| "metadata": { | |
| "collapsed": false | |
| }, | |
| "outputs": [], | |
| "source": [ | |
| "x = 'west_east'\n", | |
| "y = 'south_north'\n", | |
| "z = 'bottom_top'\n", | |
| "t = 'Time'\n", | |
| "\n", | |
| "total_rain = (rain.load()\n", | |
| " .sum(dim=[y, z], keep_attrs=True)\n", | |
| " .squeeze())" | |
| ] | |
| }, | |
| { | |
| "cell_type": "markdown", | |
| "metadata": {}, | |
| "source": [ | |
| "Plotting simple data like this is very straightforward, but as a reminder:" | |
| ] | |
| }, | |
| { | |
| "cell_type": "code", | |
| "execution_count": 28, | |
| "metadata": { | |
| "collapsed": false | |
| }, | |
| "outputs": [ | |
| { | |
| "data": { | |
| "text/plain": [ | |
| "<matplotlib.text.Text at 0x11309b810>" | |
| ] | |
| }, | |
| "execution_count": 28, | |
| "metadata": {}, | |
| "output_type": "execute_result" | |
| }, | |
| { | |
| "data": { | |
| "image/png": 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NzTqbglvFX+GtnzlbRI4FjgR2AV+o6rLEV9EkU21tLQ8//DC9evXikksuCfUK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\n", | |
| "text/plain": [ | |
| "<matplotlib.figure.Figure at 0x10fcc6390>" | |
| ] | |
| }, | |
| "metadata": {}, | |
| "output_type": "display_data" | |
| } | |
| ], | |
| "source": [ | |
| "%matplotlib inline\n", | |
| "import matplotlib.pyplot as plt\n", | |
| "\n", | |
| "fig = plt.figure()\n", | |
| "ax = fig.add_subplot(111, aspect=200.)\n", | |
| "\n", | |
| "lines = ax.plot(total_rain[x], total_rain, color='k', lw=2)\n", | |
| "ax.set_xlabel(x)\n", | |
| "ax.set_ylabel(\"Total rain ({})\".format(total_rain.units))" | |
| ] | |
| }, | |
| { | |
| "cell_type": "markdown", | |
| "metadata": {}, | |
| "source": [ | |
| "---\n", | |
| "\n", | |
| "That's the basic example. Suppose, now, we wanted to visualize contours of liquid water content in a 2D slice of the storm? That's easy to do using the aggregation features from `xray` and the same basic plotting interface. However, we'll also use the \"selection\" feature to choose a slice through the model domain; see [here](http://xray.readthedocs.org/en/stable/indexing.html) for more." | |
| ] | |
| }, | |
| { | |
| "cell_type": "code", | |
| "execution_count": 54, | |
| "metadata": { | |
| "collapsed": true | |
| }, | |
| "outputs": [], | |
| "source": [ | |
| "liq_water = dataset['QRAIN'] + dataset['QCLOUD']\n", | |
| "liq_water.attrs['long_name'] = \"Total water mixing ratio\"\n", | |
| "liq_water.attrs['units'] = \"kg/kg\"\n", | |
| "\n", | |
| "liq_water_slice = (liq_water.load()\n", | |
| " .isel(south_north=slice(30, 70),\n", | |
| " bottom_top=slice(0, 40),\n", | |
| " west_east=slice(100, 320))\n", | |
| " .mean(y, keep_attrs=True)\n", | |
| " .squeeze())" | |
| ] | |
| }, | |
| { | |
| "cell_type": "code", | |
| "execution_count": 73, | |
| "metadata": { | |
| "collapsed": false | |
| }, | |
| "outputs": [ | |
| { | |
| "data": { | |
| "image/png": 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wJfDBqg0viJH6+4z8BkK0pf5HA3eo6s0Aqvoz4B7gT2jR/XdFSDuVjVREFuI1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\nYII=\n", | |
| "text/plain": [ | |
| "<matplotlib.figure.Figure at 0x1157ea5d0>" | |
| ] | |
| }, | |
| "metadata": {}, | |
| "output_type": "display_data" | |
| } | |
| ], | |
| "source": [ | |
| "from matplotlib.colors import BoundaryNorm\n", | |
| "\n", | |
| "levels = [0, 1e-5, 2e-5, 5e-5, 1e-4, 2e-4, 5e-4, 1e-3, 2e-3, ]\n", | |
| "cmap = plt.get_cmap(\"Oranges\")\n", | |
| "norm = BoundaryNorm(levels, ncolors=cmap.N, clip=True)\n", | |
| "\n", | |
| "fig = plt.figure(figsize=(5., 4.))\n", | |
| "ax = fig.add_subplot(111)\n", | |
| "\n", | |
| "cf = ax.contourf(liq_water_slice, \n", | |
| " levels=levels, cmap=cmap, norm=norm)\n", | |
| "cb = plt.colorbar(cf, ax=ax, orientation='horizontal', format=\"%1.0e\")" | |
| ] | |
| }, | |
| { | |
| "cell_type": "code", | |
| "execution_count": 74, | |
| "metadata": { | |
| "collapsed": true | |
| }, | |
| "outputs": [], | |
| "source": [ | |
| "pres = (dataset['P'] + dataset['PB']) * 0.01\n", | |
| "pres.attrs['long_name'] = 'Total pressure'\n", | |
| "pres.attrs['units'] = 'mb'" | |
| ] | |
| } | |
| ], | |
| "metadata": { | |
| "kernelspec": { | |
| "display_name": "Python 2", | |
| "language": "python", | |
| "name": "python2" | |
| }, | |
| "language_info": { | |
| "codemirror_mode": { | |
| "name": "ipython", | |
| "version": 2 | |
| }, | |
| "file_extension": ".py", | |
| "mimetype": "text/x-python", | |
| "name": "python", | |
| "nbconvert_exporter": "python", | |
| "pygments_lexer": "ipython2", | |
| "version": "2.7.10" | |
| } | |
| }, | |
| "nbformat": 4, | |
| "nbformat_minor": 0 | |
| } |
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Hi, how can you convert the z-coordinate using python. Because wrf uses sigma coordinate in z direction. So how do you interpolate the sigma level to pressure level?