from mpl_toolkits.basemap import Basemap, cm, shiftgrid, interp
from netCDF4 import Dataset as NetCDFFile
import numpy as N
import matplotlib.pyplot as plt
import glob
import numpy.ma as ma
from scipy.interpolate import griddata
import scipy.stats
from matplotlib.dates import DateFormatter
import datetime
country = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/Ctry_halfdeg.nc', 'r')
#print iizumi
coun = country.variables['MASK_Country'][:, :]
#area=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/gridareahalf.nc','r')
#gridarea = area.variables['cell_area'][:,:]
#gridlon = area.variables['lon'][:]
#gridarea,gridlon = shiftgrid(180.5,gridarea,gridlon,start=False)
def annualyield(year, couna, counb):
bb = year - 2006
region1 = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/RCP85_crop_150901.nc',
'r')
maitrop = region1.variables['maize_trop'][bb, :, :]
maitemp = region1.variables['maize_temp'][bb, :, :]
maitropi = region1.variables['maize_trop_irrig'][bb, :, :]
def draw_velocity_map(nc_file_name):
nc = NetCDFFile(nc_file_name, 'r+')
lat = nc.variables['nav_lat_grid_U'][:]
lon = nc.variables['nav_lon_grid_U'][:]
vel_dir = "samples/bad/vel/"
nc_name = nc_file_name.split("/")[4].split(".")[0]
velocity = np.zeros((400, 1100), dtype=np.float32)
for file_name in os.listdir(vel_dir):
if nc_name in file_name:
square = img.load_square_from_file(vel_dir +
file_name.split(".")[0])
print(file_name)
print(str(np.min(square)) + "; " + str(np.max(square)))
square_index = data.extract_square_index(vel_dir +
file_name.split(".")[0])
x = int(square_index.split("_")[0])
y = int(square_index.split("_")[1])
print(str(x) + " " + str(y))
velocity[y:y + 100, x:x + 100] = square
nc.close()
lat_left_bottom = lat[-1][-1]
lon_left_bottom = lon[-1][-1]
lat_right_top = lat[0][0]
lon_right_top = lon[0][0]
lat_center = 90
# 110, 119
lon_center = 110
m = Basemap(projection='stere',
lon_0=lon_center,
lat_0=lat_center,
resolution='l',
llcrnrlat=lat_left_bottom,
llcrnrlon=lon_left_bottom,
urcrnrlat=lat_right_top,
urcrnrlon=lon_right_top)
m.pcolormesh(lon, lat, velocity, latlon=True, cmap='RdYlBu_r', vmax=0.6)
m.drawcoastlines()
m.drawcountries()
m.fillcontinents(color='#cc9966', lake_color='#99ffff')
# plt.rcParams.update({'font.size': 22})
ax = plt.gca()
# ax.tick_params(labelsize=10)
divider = make_axes_locatable(ax)
cax = divider.append_axes("right", size="5%", pad=0.05)
plt.colorbar(cax=cax, label="Sea current velocity")
# plt.title("Anomalies detection results for: " + "20 March, 2013")
model = load_model("samples/current_model/model.h5")
valid_squares = [[*list(range(1, 10))]]
with open("samples/valid_samples.csv", 'r', newline='') as csvfile:
samples = []
reader = csv.reader(csvfile, delimiter=',')
for row in reader:
if "samples/bad/vel/" + nc_name in row[0]:
print(row)
samples.append(row)
square_index = data.extract_square_index(row[0])
x = int(square_index.split("_")[0])
y = int(square_index.split("_")[1])
if (x >= 100) and (x < 1000) and (y < 300):
sample = np.zeros((1, 100, 100, 1), dtype=np.float32)
square = np.expand_dims(img.load_square_from_file(row[0]),
axis=2)
sample[0] = square
result = model.predict(sample)
result_x, result_y = m(lon[y + 50][x + 50],
lat[y + 50][x + 50])
ax.text(result_x,
result_y,
"%0.3f" % result[0][0],
ha='center',
size=7,
color="yellow",
path_effects=[
PathEffects.withStroke(linewidth=3,
foreground='black')
])
if row[1] == "1":
print("outlier!")
lat_poly = np.array([
lat[y][x], lat[y][x + 99], lat[y + 99][x + 99],
lat[y + 99][x]
])
lon_poly = np.array([
lon[y][x], lon[y][x + 99], lon[y + 99][x + 99],
lon[y + 99][x]
])
mapx, mapy = m(lon_poly, lat_poly)
points = np.zeros((4, 2), dtype=np.float32)
for j in range(0, 4):
points[j][0] = mapx[j]
points[j][1] = mapy[j]
if result[0][0] > 0.5:
poly = Polygon(points,
color='green',
fill=False,
linewidth=3)
ax.add_patch(poly)
else:
poly = Polygon(points,
color='red',
fill=False,
linewidth=3)
ax.add_patch(poly)
else:
if result[0][0] > 0.5:
lat_poly = np.array([
lat[y][x], lat[y][x + 99], lat[y + 99][x + 99],
lat[y + 99][x]
])
lon_poly = np.array([
lon[y][x], lon[y][x + 99], lon[y + 99][x + 99],
lon[y + 99][x]
])
mapx, mapy = m(lon_poly, lat_poly)
points = np.zeros((4, 2), dtype=np.float32)
for j in range(0, 4):
points[j][0] = mapx[j]
points[j][1] = mapy[j]
poly = Polygon(points,
color='red',
fill=False,
linewidth=3)
ax.add_patch(poly)
print(result)
# plt.show()
red = Patch(color='red', label='Error')
green = Patch(color='green', label='Correct')
plt.legend(loc='lower right',
fontsize='medium',
bbox_to_anchor=(1, 1),
handles=[green, red])
plt.savefig("test" + "_bad_result.png", dpi=500)
def draw_map(nc_file_name):
nc = NetCDFFile(nc_file_name, 'r+')
lat = nc.variables['nav_lat_grid_U'][:]
lon = nc.variables['nav_lon_grid_U'][:]
nc_name = nc_file_name.split("/")[4].split(".")[0]
velocity = np.zeros((400, 1100), dtype=np.float32)
vel_dir = "samples/bad/vel/"
for file_name in os.listdir(vel_dir):
if nc_name in file_name:
square = img.load_square_from_file(vel_dir +
file_name.split(".")[0])
print(file_name)
print(str(np.min(square)) + "; " + str(np.max(square)))
square_index = data.extract_square_index(vel_dir +
file_name.split(".")[0])
x = int(square_index.split("_")[0])
y = int(square_index.split("_")[1])
print(str(x) + " " + str(y))
velocity[y:y + 100, x:x + 100] = square
nc.close()
lat_left_bottom = lat[-1][-1]
lon_left_bottom = lon[-1][-1]
lat_right_top = lat[0][0]
lon_right_top = lon[0][0]
lat_center = 90
# 110, 119
lon_center = 110
m = Basemap(projection='stere',
lon_0=lon_center,
lat_0=lat_center,
resolution='l',
llcrnrlat=lat_left_bottom,
llcrnrlon=lon_left_bottom,
urcrnrlat=lat_right_top,
urcrnrlon=lon_right_top)
m.pcolormesh(lon, lat, velocity, latlon=True, cmap='RdYlBu_r', vmax=0.6)
m.drawcoastlines()
m.drawcountries()
m.fillcontinents(color='#cc9966', lake_color='#99ffff')
ax = plt.gca()
# ax.tick_params(labelsize=10)
divider = make_axes_locatable(ax)
cax = divider.append_axes("right", size="5%", pad=0.05)
plt.colorbar(cax=cax, label="Sea current velocity")
# ax = plt.gca()
# divider = make_axes_locatable(ax)
# cax = divider.append_axes("right", size="5%", pad=0.05)
# plt.colorbar().set_label(label='Sea current velocity', size=15)
# with open("samples/valid_samples.csv", 'r', newline='') as csvfile:
# samples = []
#
# reader = csv.reader(csvfile, delimiter=',')
# for row in reader:
# if "samples/bad/vel/" + nc_name in row[0]:
# print(row)
# samples.append(row)
# square_index = data.extract_square_index(row[0])
#
# x = int(square_index.split("_")[0])
# y = int(square_index.split("_")[1])
#
# if (x >= 100) and (x < 1000) and (y < 300):
#
# sample = np.zeros((1, 100, 100, 1), dtype=np.float32)
# square = np.expand_dims(img.load_square_from_file(row[0]), axis=2)
# sample[0] = square
# lat_poly = np.array([lat[y][x], lat[y][x + 99], lat[y + 99][x + 99], lat[y + 99][x]])
# lon_poly = np.array([lon[y][x], lon[y][x + 99], lon[y + 99][x + 99], lon[y + 99][x]])
# mapx, mapy = m(lon_poly, lat_poly)
# points = np.zeros((4, 2), dtype=np.float32)
# for j in range(0, 4):
# points[j][0] = mapx[j]
# points[j][1] = mapy[j]
# poly = Polygon(points, color='black', fill=False, linewidth=3)
# ax.add_patch(poly)
# plt.savefig("levels" + "_!!!.png", dpi=500)
plt.show()
from mpl_toolkits.basemap import Basemap, cm, shiftgrid,interp,maskoceans
from netCDF4 import Dataset as NetCDFFile
import numpy as N
import matplotlib.pyplot as plt
import numpy.ma as ma
import matplotlib.colors as colors
mask=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/Ctry_halfdeg.nc','r')
cou1 = mask.variables['MASK_Country'][:,:]
cou1= ma.masked_where(cou1<=0.0,cou1)
region=NetCDFFile('/project/projectdirs/m1602/datasets4.full/surfdata_05x05.nc','r')
ind = region.variables['REGION_MASK_CRU_NCEP'][:,:]
#area=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/gridareahalf.nc','r')
#gridarea = area.variables['cell_area']
isam=NetCDFFile('/scratch2/scratchdirs/tslin2/isam/rice_cheyenne/his_cru/ric_irr_fert/output/ric_irr_fert.nc','r')
lonisam1=isam.variables['lon'][:]
#ric_i_f=isam.variables['totalyield'][96:103,:,:]
#riceb=N.average(ric_i_f,axis=0)
spam=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/spamsoy_isam.nc','r')
spamy=spam.variables['soyy_total'][:,:]
spampro=spam.variables['soyp_total'][:,:]
spamarea=spam.variables['soya_total'][:,:]
#riceb,lona11=shiftgrid(180.5,riceb,lonisam1,start=False)
print('this one is for chlorophyll 1 in 2006')
from netCDF4 import Dataset as NetCDFFile
import numpy as np
from datetime import datetime as dt
mydirectory = '/users/asmit101/data/stuff/2006_mod8_run6a_NAM'
nc = NetCDFFile(mydirectory + '/surfchl_whole_year.nc')
print(nc.variables.keys())
chlorophyll1 = nc.variables['chlorophyll1'][:]
time = nc.variables['ocean_time'][:]
timearray = []
for i in time:
timearray.append(dt.fromtimestamp(i))
for j in timearray:
print(j)
print(chlorophyll1.ndim)
chlorophyll1array = []
chlorophyll1 = chlorophyll1.mean(axis=tuple(range(2, 4)))
for i in chlorophyll1:
chlorophyll1array.append(float(i))
print(chlorophyll1array)
print(timearray)
filename5a = '/data/scihub-users/giyoung/PWRF_V3.6.1/RUNS/MAC_WRF/56_DeMott_WATSAT_10xHM_noThresh_eta70_MYNN/wrfout_d01_2015-11-27_00:00:00'
###################################
# Extract domain number:
###################################
domainno_start = filename1.find('/wrfout_') + 8
domainno_end = filename1.find('_2015',domainno_start)
domainno1 = filename1[domainno_start:domainno_end]
del domainno_end, domainno_start
###################################
# LOAD NETCDF FILE
###################################
nc1 = NetCDFFile(filename1, 'r')
nc2 = NetCDFFile(filename2, 'r')
nc3 = NetCDFFile(filename3, 'r')
nc4 = NetCDFFile(filename4, 'r')
nc5 = NetCDFFile(filename5, 'r')
nc1a = NetCDFFile(filename1a, 'r')
nc2a = NetCDFFile(filename2a, 'r')
nc3a = NetCDFFile(filename3a, 'r')
nc4a = NetCDFFile(filename4a, 'r')
nc5a = NetCDFFile(filename5a, 'r')
###################################
# DEFINE TEMPERATURE BINNING
###################################
mx = maximum_filter(mat, size=window, mode=mode)
# (mat == mx) true if pixel is equal to the local max
# (mat == mn) true if pixel is equal to the local in
# Return the indices of the maxima, minima
return np.nonzero(mat == mn), np.nonzero(mat == mx)
if len(sys.argv) < 2:
print 'enter date to plot (YYYYMMDDHH) on command line'
raise SystemExit
# get date from command line.
YYYYMMDDHH = sys.argv[1]
# open OpenDAP dataset.
try:
data=NetCDFFile("http://nomad1.ncep.noaa.gov:9090/dods/gdas/rotating/gdas"+YYYYMMDDHH+".grib2")
except:
data=NetCDFFile("http://nomad2.ncep.noaa.gov:9090/dods/gdas/rotating/gdas"+YYYYMMDDHH+".grib2")
# read lats,lons.
lats = data.variables['lat'][:]
lons1 = data.variables['lon'][:]
nlats = len(lats)
nlons = len(lons1)
# read prmsl, convert to hPa (mb).
prmsl = 0.01*data.variables['prmslmsl'][0]
# the window parameter controls the number of highs and lows detected.
# (higher value, fewer highs and lows)
local_min, local_max = extrema(prmsl, mode='wrap', window=25)
# create Basemap instance.
m =\
x, y = map(lons * 180. / np.pi, lats * 180. / np.pi)
# contour data over the map.
cs = map.contour(x, y, wave + mean, 15, linewidths=1.5)
plt.title('contour lines over filled continent background')
plt.show()
from mpl_toolkits.basemap import Basemap, cm
# requires netcdf4-python (netcdf4-python.googlecode.com)
from netCDF4 import Dataset as NetCDFFile
import numpy as np
import matplotlib.pyplot as plt
# plot rainfall from NWS using special precipitation
# colormap used by the NWS, and included in basemap.
nc = NetCDFFile('../../../examples/nws_precip_conus_20061222.nc')
# data from http://water.weather.gov/precip/
prcpvar = nc.variables['amountofprecip']
data = 0.01 * prcpvar[:]
latcorners = nc.variables['lat'][:]
loncorners = -nc.variables['lon'][:]
lon_0 = -nc.variables['true_lon'].getValue()
lat_0 = nc.variables['true_lat'].getValue()
# create figure and axes instances
fig = plt.figure(figsize=(8, 8))
ax = fig.add_axes([0.1, 0.1, 0.8, 0.8])
# create polar stereographic Basemap instance.
m = Basemap(projection='stere',
lon_0=lon_0,
lat_0=90.,
lat_ts=lat_0,
metavar="NUMBER")
options, args = parser.parse_args()
if not options.filename:
options.filename = 'landice_grid.nc'
print('No file specified. Attempting to use landice_grid.nc')
if not options.afile:
sys.exit(
"Error: A restart file from test B5 is required to set up this test. Specify with -b"
)
# copy the restart file to be the new input file
shutil.copyfile(options.afile, options.filename)
# Open the file, get needed dimensions
gridfile = NetCDFFile(options.filename, 'r+')
StrLen = len(gridfile.dimensions['StrLen'])
gridfile.variables['xtime'][0, :] = netCDF4.stringtoarr(
'0000-01-01_00:00:00'.ljust(StrLen), StrLen)
gridfile.variables['simulationStartTime'][:] = netCDF4.stringtoarr(
'0000-01-01_00:00:00'.ljust(StrLen), StrLen)
# modify melt inputs
gridfile.variables['externalWaterInput'][
0, :] = gridfile.variables['externalWaterInput'][
0, :] * 1.0e-12 # Make value at moulin locations tiny but positive
# value for basalMeltInput doesn't matter, because it will be overwritten in the code.
gridfile.close()
print('Successfully added initial conditions to: ' + options.filename)
from mpl_toolkits.basemap import Basemap, cm, shiftgrid, interp
from netCDF4 import Dataset as NetCDFFile
import numpy as N
import matplotlib.pyplot as plt
import glob
import numpy.ma as ma
from scipy.interpolate import griddata
import matplotlib.colors as colors
area1 = NetCDFFile(
'/project/projectdirs/m1602/datasets4.full/surfdata_05x05.nc', 'r')
mask = area1.variables['REGION_MASK_CRU_NCEP'][:, :]
area = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/gridareahalf_isam.nc',
'r')
gridarea1 = area.variables['cell_area'][:, :]
gridlon = area.variables['lon'][:]
gridlat = area.variables['lat'][:]
#print gridlon
nclu = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/m3yield_isam.nc', 'r')
ncvar_maize = nclu.variables['maizey'][0, :, :]
marea = nclu.variables['maize_area'][0, :, :]
region1 = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/HistoricalGLM_crop_150901.nc',
'r')
maitrop = region1.variables['maize_trop'][95:105, :, :]
maitemp = region1.variables['maize_temp'][95:105, :, :]
maitropi = region1.variables['maize_trop_irrig'][95:105, :, :]
maitempi = region1.variables['maize_temp_irrig'][95:105, :, :]
from mpl_toolkits.basemap import Basemap, cm, shiftgrid, interp, maskoceans
from netCDF4 import Dataset as NetCDFFile
import numpy as N
import matplotlib.pyplot as plt
import numpy.ma as ma
from statsmodels.stats.weightstats import DescrStatsW
import matplotlib.colors as colors
region = NetCDFFile(
'/global/project/projectdirs/m1602/datasets4.full/arbit_init_state_05x05.nc',
'r')
ind = region.variables['REGION_MASK'][:, :]
lonisam1 = region.variables['lon'][:]
ind, lona11 = shiftgrid(180.5, ind, lonisam1, start=False)
area = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/gridareahalf.nc', 'r')
gridarea = area.variables['cell_area'][:, :]
nclu = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/maize_AreaYieldProduction.nc',
'r')
ncvar_m = nclu.variables['maizeData'][0, 0, :, :]
ncvar_y = nclu.variables['maizeData'][0, 1, :, :]
ncvar_a = nclu.variables['maizeData'][0, 4, :, :]
ncvar_p = nclu.variables['maizeData'][0, 5, :, :]
nclu1 = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/soybean_AreaYieldProduction.nc',
'r')
ncvar_ms = nclu1.variables['soybeanData'][0, 0, :, :]
ncvar_ys = nclu1.variables['soybeanData'][0, 1, :, :]
def yieldout(year):
bb=year-1900
region1=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/HistoricalGLM_crop_150901.nc','r')
maitrop = region1.variables['maize_trop'][bb-1,:,:]
maitemp = region1.variables['maize_temp'][bb-1,:,:]
maitropi=region1.variables['maize_trop_irrig'][bb-1,:,:]
maitempi=region1.variables['maize_temp_irrig'][bb-1,:,:]
gridarea = region1.variables['area'][:,:]
maitrop=ma.masked_where(maitrop<=0,maitrop)
maitrop=ma.filled(maitrop, fill_value=0.)
maitemp=ma.masked_where(maitemp<=0,maitemp)
maitemp=ma.filled(maitemp, fill_value=0.)
maitropi=ma.masked_where(maitropi<=0,maitropi)
maitropi=ma.filled(maitropi, fill_value=0.)
maitempi=ma.masked_where(maitempi<=0,maitempi)
maitempi=ma.filled(maitempi, fill_value=0.)
maizetor=maitrop+maitemp
maizetoi=maitropi+maitempi
maizetrop=maitrop+maitropi
maizetemp=maitemp+maitempi
maizeto = maitrop+maitemp+maitropi+maitempi
ff=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/HistoricalFertilizer.nc','r')
fert_maitrop = ff.variables['maize_trop_fert'][bb-1,:,:]
fert_maitemp = ff.variables['maize_temp_fert'][bb-1,:,:]
clm=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45historical/maizetrop_historical_co2_rf_fert_0.5x0.5.nc','r')
# clmtropf = clm.variables['yield'][bb,:,:]
clmtropfer=clm.variables['fertilizer'][bb-1,:,:]
clm1=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45historical/maizetemp_historical_co2_rf_fert_0.5x0.5.nc','r')
# clmtempf = clm1.variables['yield'][bb,:,:]
clmtempfer=clm1.variables['fertilizer'][bb-1,:,:]
isam=NetCDFFile('/scratch2/scratchdirs/tslin2/isam/cheyenne/yieldout/isamhistorical/heat/maizetrop_historical_co2_rf_fert_0.5x0.5.nc','r')
clmtropf = isam.variables['totalyield'][bb,:,:]
isam1=NetCDFFile('/scratch2/scratchdirs/tslin2/isam/cheyenne/yieldout/isamhistorical/heat/maizetemp_historical_co2_rf_fert_0.5x0.5.nc','r')
clmtempf = isam1.variables['totalyield'][bb,:,:]
clm2=NetCDFFile('/scratch2/scratchdirs/tslin2/isam/cheyenne/yieldout/isamhistorical/heat/maizetrop_historical_co2_irrig_fert_0.5x0.5.nc','r')
clmtropfi = clm2.variables['totalyield'][bb,:,:]
clm3=NetCDFFile('/scratch2/scratchdirs/tslin2/isam/cheyenne/yieldout/isamhistorical/heat/maizetemp_historical_co2_irrig_fert_0.5x0.5.nc','r')
clmtempfi = clm3.variables['totalyield'][bb,:,:]
clma=NetCDFFile('/scratch2/scratchdirs/tslin2/isam/cheyenne/yieldout/isamhistorical/heat/maizetrop_historical_co2_rf_nofert_0.5x0.5.nc','r')
clmtropfno = clma.variables['totalyield'][bb,:,:]
clm1a=NetCDFFile('/scratch2/scratchdirs/tslin2/isam/cheyenne/yieldout/isamhistorical/heat/maizetemp_historical_co2_rf_nofert_0.5x0.5.nc','r')
clmtempfno = clm1a.variables['totalyield'][bb,:,:]
clm2a=NetCDFFile('/scratch2/scratchdirs/tslin2/isam/cheyenne/yieldout/isamhistorical/heat/maizetrop_historical_co2_irrig_nofert_0.5x0.5.nc','r')
clmtropfnoi = clm2a.variables['totalyield'][bb,:,:]
clm3a=NetCDFFile('/scratch2/scratchdirs/tslin2/isam/cheyenne/yieldout/isamhistorical/heat/maizetemp_historical_co2_irrig_nofert_0.5x0.5.nc','r')
clmtempfnoi = clm3a.variables['totalyield'][bb,:,:]
lonisam=clm3a.variables['lon'][:]
clmtempfnoi,lonisam1 = shiftgrid(180.5,clmtempfnoi,lonisam,start=False)
clmtropfnoi,lonisam1 = shiftgrid(180.5,clmtropfnoi,lonisam,start=False)
clmtempfno,lonisam1 = shiftgrid(180.5,clmtempfno,lonisam,start=False)
clmtropfno,lonisam1 = shiftgrid(180.5,clmtropfno,lonisam,start=False)
clmtempf,lonisam1 = shiftgrid(180.5,clmtempf,lonisam,start=False)
clmtropf,lonisam1 = shiftgrid(180.5,clmtropf,lonisam,start=False)
clmtempfi,lonisam1 = shiftgrid(180.5,clmtempfi,lonisam,start=False)
clmtropfi,lonisam1 = shiftgrid(180.5,clmtropfi,lonisam,start=False)
#print lonisam1
clmtropfer=N.flipud(clmtropfer)
clmtempfer=N.flipud(clmtempfer)
clmtropf= ma.masked_where(maitrop<=0,clmtropf)
clmtempf= ma.masked_where(maitemp<=0,clmtempf)
clmtropf=ma.filled(clmtropf, fill_value=0.)
clmtempf=ma.filled(clmtempf, fill_value=0.)
clmtropfi= ma.masked_where(maitropi<=0,clmtropfi)
clmtempfi= ma.masked_where(maitempi<=0,clmtempfi)
clmtropfi=ma.filled(clmtropfi, fill_value=0.)
clmtempfi=ma.filled(clmtempfi, fill_value=0.)
clmtropfno= ma.masked_where(maitrop<=0,clmtropfno)
clmtempfno= ma.masked_where(maitemp<=0,clmtempfno)
clmtropfno=ma.filled(clmtropfno, fill_value=0.)
clmtempfno=ma.filled(clmtempfno, fill_value=0.)
clmtropfnoi= ma.masked_where(maitropi<=0,clmtropfnoi)
clmtempfnoi= ma.masked_where(maitempi<=0,clmtempfnoi)
clmtropfnoi=ma.filled(clmtropfnoi, fill_value=0.)
clmtempfnoi=ma.filled(clmtempfnoi, fill_value=0.)
fertfractiontrop= N.zeros((360, 720))
nofertfractiontrop= N.zeros((360, 720))
fertfractiontemp= N.zeros((360, 720))
nofertfractiontemp= N.zeros((360, 720))
for x in range(0,360):
for y in range(0,720):
if clmtropfer[x,y] > 0.0:
fertfractiontrop[x,y] = min(1.0,fert_maitrop[x,y]/clmtropfer[x,y])
nofertfractiontrop[x,y] = 1.0 - fertfractiontrop[x,y]
else:
fertfractiontrop[x,y]= 0.0
nofertfractiontrop[x,y] = 1.0
for x in range(0,360):
for y in range(0,720):
if clmtempfer[x,y] > 0.0:
fertfractiontemp[x,y] = min(1.0,fert_maitemp[x,y]/clmtempfer[x,y])
nofertfractiontemp[x,y] = 1.0 - fertfractiontemp[x,y]
else:
fertfractiontemp[x,y]= 0.0
nofertfractiontemp[x,y] = 1.0
clmtropfnew= N.zeros((360, 720))
clmtempfnew= N.zeros((360, 720))
clmtropfinew= N.zeros((360, 720))
clmtempfinew= N.zeros((360, 720))
for x in range(0,360):
for y in range(0,720):
clmtropfnew[x,y] = (nofertfractiontrop[x,y]*clmtropfno[x,y])+(fertfractiontrop[x,y]*clmtropf[x,y])
clmtempfnew[x,y] = (nofertfractiontemp[x,y]*clmtempfno[x,y])+(fertfractiontemp[x,y]*clmtempf[x,y])
clmtropfinew[x,y] = (nofertfractiontrop[x,y]*clmtropfnoi[x,y])+(fertfractiontrop[x,y]*clmtropfi[x,y])
clmtempfinew[x,y] = (nofertfractiontemp[x,y]*clmtempfnoi[x,y])+(fertfractiontemp[x,y]*clmtempfi[x,y])
yield_clmtf=clmtropf+clmtempf
yield_clmtf = ma.masked_where(yield_clmtf<=0,yield_clmtf)
#yield_clmtf = ma.masked_where(maizetor<=0,yield_clmtf )
yield_clmtf=ma.filled(yield_clmtf, fill_value=0.)
yield_clmtfi=clmtropfi+clmtempfi
yield_clmtfi = ma.masked_where(yield_clmtfi<=0,yield_clmtfi)
#yield_clmtfi = ma.masked_where(maizetoi<=0,yield_clmtfi)
yield_clmtfi=ma.filled(yield_clmtfi, fill_value=0.)
yield_clmtfnew=clmtropfnew+clmtempfnew
yield_clmtfnew = ma.masked_where(yield_clmtfnew<=0,yield_clmtfnew)
#yield_clmtf = ma.masked_where(maizetor<=0,yield_clmtf )
yield_clmtfnew=ma.filled(yield_clmtfnew, fill_value=0.)
yield_clmtfinew=clmtropfinew+clmtempfinew
yield_clmtfinew = ma.masked_where(yield_clmtfinew<=0,yield_clmtfinew)
#yield_clmtfi = ma.masked_where(maizetoi<=0,yield_clmtfi)
yield_clmtfinew=ma.filled(yield_clmtfinew, fill_value=0.)
area=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/gridareahalf.nc','r')
gridarea = area.variables['cell_area'][:,:]
gridlon = area.variables['lon'][:]
gridlat=area.variables['lat'][:]
gridarea,gridlon = shiftgrid(180.5,gridarea,gridlon,start=False)
lon2,lat2 = N.meshgrid(gridlon,gridlat)
map = Basemap(projection ='cyl', llcrnrlat=-65, urcrnrlat=90,llcrnrlon=-180, urcrnrlon=180, resolution='c')
x,y = map(lon2,lat2)
yield_clmtf=maskoceans(x,y,yield_clmtf)
yield_clmtf = ma.masked_where(maizeto<=0,yield_clmtf)
yield_clmtfi=maskoceans(x,y,yield_clmtfi)
yield_clmtfi = ma.masked_where(maizeto<=0,yield_clmtfi)
clmy=((yield_clmtf*maizetor*gridarea)+(yield_clmtfi*maizetoi*gridarea))/((maizetoi*gridarea)+(maizetor*gridarea))
yield_clmtfnew=maskoceans(x,y,yield_clmtfnew)
yield_clmtfnew = ma.masked_where(maizeto<=0,yield_clmtfnew)
yield_clmtfinew=maskoceans(x,y,yield_clmtfinew)
yield_clmtfinew = ma.masked_where(maizeto<=0,yield_clmtfinew)
clmynew=((yield_clmtfnew*maizetor*gridarea)+(yield_clmtfinew*maizetoi*gridarea))/((maizetoi*gridarea)+(maizetor*gridarea))
return clmy
yield_clmtfinew=maskoceans(x,y,yield_clmtfinew)
yield_clmtfinew = ma.masked_where(maizeto<=0,yield_clmtfinew)
clmynew=((yield_clmtfnew*maizetor*gridarea)+(yield_clmtfinew*maizetoi*gridarea))/((maizetoi*gridarea)+(maizetor*gridarea))
return clmy
yief= N.zeros((105, 360, 720))
years = range(1901, 2006)
for i, yeara in enumerate(years):
yie=yieldout(yeara)
yief[i, :, :] = yie
area=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/gridareahalf.nc','r')
gridarea = area.variables['cell_area'][:,:]
gridlon = area.variables['lon'][:]
gridlat=area.variables['lat'][:]
gridarea,gridlon = shiftgrid(180.5,gridarea,gridlon,start=False)
#print gridlon
ncfile=NetCDFFile('isamhis_maiscaleiyield_heat.nc','w',format='NETCDF3_64BIT_OFFSET')
ncfile.createDimension('lat', 360)
ncfile.createDimension('lon', 720)
ncfile.createDimension('time', 105)
times = ncfile.createVariable('time', 'f8', ('time',))
latitudes = ncfile.createVariable('lat', 'f8', ('lat',))
longitudes = ncfile.createVariable('lon', 'f8', ('lon',))
def annualyield(year, couna, counb):
bb = year - 2006
region1 = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/RCP85_crop_150901.nc',
'r')
maitrop = region1.variables['maize_trop'][bb, :, :]
maitemp = region1.variables['maize_temp'][bb, :, :]
maitropi = region1.variables['maize_trop_irrig'][bb, :, :]
maitempi = region1.variables['maize_temp_irrig'][bb, :, :]
gridarea = region1.variables['area'][:, :]
maitrop = ma.masked_where(maitrop <= 0, maitrop)
maitrop = ma.filled(maitrop, fill_value=0.)
maitemp = ma.masked_where(maitemp <= 0, maitemp)
maitemp = ma.filled(maitemp, fill_value=0.)
maitropi = ma.masked_where(maitropi <= 0, maitropi)
maitropi = ma.filled(maitropi, fill_value=0.)
maitempi = ma.masked_where(maitempi <= 0, maitempi)
maitempi = ma.filled(maitempi, fill_value=0.)
maizetro = maitrop + maitropi
maizetem = maitemp + maitempi
maizetor = maitrop + maitemp
maizetoi = maitropi + maitempi
maizeto = maitrop + maitemp + maitropi + maitempi
clm = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp85/maizetrop_rcp85_constco2_rf_nofert_0.5x0.5.nc',
'r')
clmtropf = clm.variables['yield'][bb, :, :]
clm1 = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp85/maizetemp_rcp85_constco2_rf_nofert_0.5x0.5.nc',
'r')
clmtempf = clm1.variables['yield'][bb, :, :]
clm2 = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp85/maizetrop_rcp85_co2_rf_nofert_0.5x0.5.nc',
'r')
clmtropfi = clm2.variables['yield'][bb, :, :]
clm3 = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp85/maizetemp_rcp85_co2_rf_nofert_0.5x0.5.nc',
'r')
clmtempfi = clm3.variables['yield'][bb, :, :]
clmtropf = N.flipud(clmtropf)
clmtempf = N.flipud(clmtempf)
clmtropfi = N.flipud(clmtropfi)
clmtempfi = N.flipud(clmtempfi)
clmtropf = ma.masked_where(maizetro <= 0, clmtropf)
clmtempf = ma.masked_where(maizetem <= 0, clmtempf)
clmtropf = ma.filled(clmtropf, fill_value=0.)
clmtempf = ma.filled(clmtempf, fill_value=0.)
clmtropfi = ma.masked_where(maizetro <= 0, clmtropfi)
clmtempfi = ma.masked_where(maizetem <= 0, clmtempfi)
clmtropfi = ma.filled(clmtropfi, fill_value=0.)
clmtempfi = ma.filled(clmtempfi, fill_value=0.)
yield_clmtf = clmtropf + clmtempf
yield_clmtf = ma.masked_where(yield_clmtf <= 0, yield_clmtf)
yield_clmtf = ma.masked_where(maizeto <= 0, yield_clmtf)
yield_clmtf = ma.filled(yield_clmtf, fill_value=0.)
yield_clmtfi = clmtropfi + clmtempfi
yield_clmtfi = ma.masked_where(yield_clmtfi <= 0, yield_clmtfi)
yield_clmtfi = ma.masked_where(maizeto <= 0, yield_clmtfi)
yield_clmtfi = ma.filled(yield_clmtfi, fill_value=0.)
clmn = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp85/maizetrop_rcp85_co2_rf_fert_0.5x0.5.nc',
'r')
clmtropfn = clmn.variables['yield'][bb, :, :]
clm1n = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp85/maizetemp_rcp85_co2_rf_fert_0.5x0.5.nc',
'r')
clmtempfn = clm1n.variables['yield'][bb, :, :]
clm2n = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp85/maizetrop_rcp85_co2_irrig_fert_0.5x0.5.nc',
'r')
clmtropfin = clm2n.variables['yield'][bb, :, :]
clm3n = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp85/maizetemp_rcp85_co2_irrig_fert_0.5x0.5.nc',
'r')
clmtempfin = clm3n.variables['yield'][bb, :, :]
clmtropfn = N.flipud(clmtropfn)
clmtempfn = N.flipud(clmtempfn)
clmtropfin = N.flipud(clmtropfin)
clmtempfin = N.flipud(clmtempfin)
clmtropfn = ma.masked_where(maizetro <= 0, clmtropfn)
clmtempfn = ma.masked_where(maizetem <= 0, clmtempfn)
clmtropfn = ma.filled(clmtropfn, fill_value=0.)
clmtempfn = ma.filled(clmtempfn, fill_value=0.)
clmtropfin = ma.masked_where(maizetro <= 0, clmtropfin)
clmtempfin = ma.masked_where(maizetem <= 0, clmtempfin)
clmtropfin = ma.filled(clmtropfin, fill_value=0.)
clmtempfin = ma.filled(clmtempfin, fill_value=0.)
yield_clmtfn = clmtropfn + clmtempfn
yield_clmtfn = ma.masked_where(yield_clmtfn <= 0, yield_clmtfn)
yield_clmtfn = ma.masked_where(maizeto <= 0, yield_clmtfn)
yield_clmtfn = ma.filled(yield_clmtfn, fill_value=0.)
yield_clmtfin = clmtropfin + clmtempfin
yield_clmtfin = ma.masked_where(yield_clmtfin <= 0, yield_clmtfin)
yield_clmtfin = ma.masked_where(maizeto <= 0, yield_clmtfin)
yield_clmtfin = ma.filled(yield_clmtfin, fill_value=0.)
base = NetCDFFile(
"/scratch2/scratchdirs/tslin2/isam/cheyenne/yieldout/isamrcp85/heat/maizetemp_rcp85_constco2_rf_nofert_0.5x0.5.nc",
mode='r')
base2 = NetCDFFile(
"/scratch2/scratchdirs/tslin2/isam/cheyenne/yieldout/isamrcp85/heat/maizetemp_rcp85_co2_rf_nofert_0.5x0.5.nc",
mode='r')
lona1 = base.variables["lon"][:]
lata1 = base.variables["lat"][:]
yieldf = base.variables["totalyield"][bb, :, :]
yieldfa = base2.variables["totalyield"][bb, :, :]
basei = NetCDFFile(
"/scratch2/scratchdirs/tslin2/isam/cheyenne/yieldout/isamrcp85/heat/maizetemp_rcp85_co2_rf_fert_0.5x0.5.nc",
mode='r')
base2i = NetCDFFile(
"/scratch2/scratchdirs/tslin2/isam/cheyenne/yieldout/isamrcp85/heat/maizetemp_rcp85_co2_irrig_fert_0.5x0.5.nc",
mode='r')
yieldfi = basei.variables["totalyield"][bb, :, :]
yieldfai = base2i.variables["totalyield"][bb, :, :]
baseif = NetCDFFile(
"/scratch2/scratchdirs/tslin2/isam/cheyenne/yieldout/isamrcp85/heat/maizetrop_rcp85_co2_rf_fert_0.5x0.5.nc",
mode='r')
base2if = NetCDFFile(
"/scratch2/scratchdirs/tslin2/isam/cheyenne/yieldout/isamrcp85/heat/maizetrop_rcp85_co2_irrig_fert_0.5x0.5.nc",
mode='r')
yieldfitr = baseif.variables["totalyield"][bb, :, :]
yieldfaitr = base2if.variables["totalyield"][bb, :, :]
yielda = yieldf
yield_new, lona11 = shiftgrid(180.5, yielda, lona1, start=False)
yieldb = yieldfa
yield_new1, lona11 = shiftgrid(180.5, yieldb, lona1, start=False)
yieldai = yieldfi
yield_newi, lona11 = shiftgrid(180.5, yieldai, lona1, start=False)
yieldbi = yieldfai
yield_new1i, lona11 = shiftgrid(180.5, yieldbi, lona1, start=False)
yieldaitr = yieldfitr
yield_newitr, lona11 = shiftgrid(180.5, yieldaitr, lona1, start=False)
yieldbitr = yieldfaitr
yield_new1itr, lona11 = shiftgrid(180.5, yieldbitr, lona1, start=False)
yield_new[N.isnan(yield_new)] = -9999
yield_new = ma.masked_where(yield_new <= 0, yield_new)
yield_new = ma.masked_where(maizeto <= 0, yield_new)
yield_new = ma.filled(yield_new, fill_value=0.)
yield_new1[N.isnan(yield_new1)] = -9999
yield_new1 = ma.masked_where(yield_new1 <= 0, yield_new1)
yield_new1 = ma.masked_where(maizeto <= 0, yield_new1)
yield_new1 = ma.filled(yield_new1, fill_value=0.)
yield_newi[N.isnan(yield_newi)] = -9999
yield_newi = ma.masked_where(yield_newi <= 0, yield_newi)
yield_newi = ma.masked_where(maizetem <= 0, yield_newi)
yield_newi = ma.filled(yield_newi, fill_value=0.)
yield_new1i[N.isnan(yield_new1i)] = -9999
yield_new1i = ma.masked_where(yield_new1i <= 0, yield_new1i)
yield_new1i = ma.masked_where(maizetem <= 0, yield_new1i)
yield_new1i = ma.filled(yield_new1i, fill_value=0.)
yield_newitr[N.isnan(yield_newitr)] = -9999
yield_newitr = ma.masked_where(yield_newitr <= 0, yield_newitr)
yield_newitr = ma.masked_where(maizetro <= 0, yield_newitr)
yield_newitr = ma.filled(yield_newitr, fill_value=0.)
yield_new1itr[N.isnan(yield_new1i)] = -9999
yield_new1itr = ma.masked_where(yield_new1itr <= 0, yield_new1itr)
yield_new1itr = ma.masked_where(maizetro <= 0, yield_new1itr)
yield_new1itr = ma.filled(yield_new1itr, fill_value=0.)
yield_newi = yield_newi + yield_newitr
yield_new1i = yield_new1i + yield_new1itr
yieldagf = 0.
yieldg = 0.
harea = 0.
a = 0
yieldgid = 0.
yieldgia = 0.
yieldgib = 0.
yieldgic = 0.
yieldgca = 0.
yieldgcb = 0.
yieldgcc = 0.
yieldgcd = 0.
yieldagfa = 0.
yieldagfb = 0.
yieldagfc = 0.
yieldagfd = 0.
yieldagfa1 = 0.
yieldagfb1 = 0.
yieldagfc1 = 0.
yieldagfd1 = 0.
yieldagfa = yield_new
yieldagfb = yield_new1
yieldagfc = yield_newi
yieldagfd = yield_new1i
yieldagfa1 = yield_clmtf
yieldagfb1 = yield_clmtfi
yieldagfc1 = yield_clmtfn
yieldagfd1 = yield_clmtfin
yieldagfa = ma.masked_where(yieldagfa <= 0, yieldagfa)
yieldagfb = ma.masked_where(yieldagfb <= 0, yieldagfb)
yieldagfc = ma.masked_where(yieldagfc <= 0, yieldagfc)
yieldagfd = ma.masked_where(yieldagfd <= 0, yieldagfd)
yieldagfa1 = ma.masked_where(yieldagfa1 <= 0, yieldagfa1)
yieldagfb1 = ma.masked_where(yieldagfb1 <= 0, yieldagfb1)
yieldagfc1 = ma.masked_where(yieldagfc1 <= 0, yieldagfc1)
yieldagfd1 = ma.masked_where(yieldagfd1 <= 0, yieldagfd1)
for xx in range(0, 360):
for yy in range(0, 720):
if coun[xx, yy] >= couna and coun[xx, yy] <= counb:
maizeto[xx, yy] = maizeto[xx, yy]
else:
maizeto[xx, yy] = 0
maizeto = ma.masked_where(maizeto <= 0, maizeto)
return yieldagfa, yieldagfa1, yieldagfb, yieldagfb1, yieldagfc, yieldagfc1, yieldagfd, yieldagfd1, maizeto
from mpl_toolkits.basemap import Basemap, cm, shiftgrid, interp
from netCDF4 import Dataset as NetCDFFile
import numpy as N
import matplotlib.pyplot as plt
import glob
import numpy.ma as ma
from scipy.interpolate import griddata
import matplotlib.colors as colors
from matplotlib.dates import DateFormatter
import datetime
dat = NetCDFFile(
'/scratch2/scratchdirs/tslin2/isam/maisoy_cheyenne/code/mai1901_2015region.nc',
'r')
dat1 = NetCDFFile(
'/scratch2/scratchdirs/tslin2/isam/maisoy_cheyenne/code/mairegion_rcp85.nc',
'r')
dat2 = NetCDFFile(
'/scratch2/scratchdirs/tslin2/isam/maisoy_cheyenne/code/mairegion_rcp45.nc',
'r')
for i in range(1, 6):
locals()['e{0}p'.format(i)] = dat.variables['e{0}p'.format(i)][:, :]
locals()['e{0}y'.format(i)] = dat.variables['e{0}y'.format(i)][:, :]
locals()['e{0}g'.format(i)] = dat.variables['e{0}g'.format(i)][:, :]
locals()['e{0}p85'.format(i)] = dat1.variables['e{0}p'.format(i)][:, :]
locals()['e{0}y85'.format(i)] = dat1.variables['e{0}y'.format(i)][:, :]
locals()['e{0}g85'.format(i)] = dat1.variables['e{0}g'.format(i)][:, :]
locals()['e{0}p45'.format(i)] = dat2.variables['e{0}p'.format(i)][:, :]
from mpl_toolkits.basemap import Basemap, cm, shiftgrid, interp, maskoceans
from netCDF4 import Dataset as NetCDFFile
import numpy as N
import matplotlib.pyplot as plt
import glob
import numpy.ma as ma
from scipy.interpolate import griddata
import matplotlib.colors as colors
from scipy.stats import ttest_ind
iizumi = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/iizumi/iizumi.2013JAN29.maize.1982-2006.30min.nc4',
'r')
#print iizumi
iyield = iizumi.variables['yield50'][18, :, :]
iarea = iizumi.variables['area'][18, :, :]
la = iizumi.variables['lat'][:]
lo = iizumi.variables['lon'][:]
iyield = N.flipud(iyield)
iarea = N.flipud(iarea)
region1 = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/HistoricalGLM_crop_150901.nc',
'r')
maitrop = region1.variables['maize_trop'][99, :, :]
maitemp = region1.variables['maize_temp'][99, :, :]
maitropi = region1.variables['maize_trop_irrig'][99, :, :]
maitempi = region1.variables['maize_temp_irrig'][99, :, :]
gridarea = region1.variables['area'][:, :]
maitrop = ma.masked_where(maitrop <= 0, maitrop)
maitrop = ma.filled(maitrop, fill_value=0.)
from netCDF4 import Dataset as NetCDFFile
import numpy as N
import matplotlib.pyplot as plt
import glob
import numpy.ma as ma
from scipy.interpolate import griddata
import matplotlib.colors as colors
from statsmodels.stats.weightstats import DescrStatsW
from scipy.stats import ttest_ind
from matplotlib.markers import TICKDOWN
import datetime
from matplotlib.dates import DateFormatter
from scipy import stats
area = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/gridareahalf_isam.nc',
'r')
gridarea = area.variables['cell_area'][:, :]
gridlon = area.variables['lon'][:]
gridlat = area.variables['lat'][:]
gridarea, gridlon = shiftgrid(180.5, gridarea, gridlon, start=False)
#print gridlon
nclu = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/maize_AreaYieldProduction.nc',
'r')
ncvar_maize = nclu.variables['maizeData'][:]
latnc = nclu.variables['latitude'][:]
znc = nclu.variables['level'][:]
lonnc = nclu.variables['longitude'][:]
timenc = nclu.variables['time'][:]
latnc = N.flipud(latnc)
files.append(files_c[f])
#--- Make plot for each vars and zooms.
for var in vars:
file_plot = rundir + '/' + model + '_' + var + '_apr1_' + \
yyyy_s + '_' + yyyy_e + '.nc'
syscom = 'ncra'
for f in range(len(files)):
syscom = syscom + ' ' + files[f]
syscom = syscom + ' ' + file_plot
print 'syscom = ', syscom
os.system(syscom)
print 'Loading ', var, ' from ', file_plot
nc = NetCDFFile(file_plot, 'r')
ntimes = len(nc.dimensions['Time'])
vardat = {}
dat_tmp = nc.variables[var][:,:,:]
dat_tmp = np.transpose(dat_tmp)
vardat[var] = dat_tmp
nc.close()
titlein = model.upper() + ', ' + var_lab[var] + ', ' + \
'Apr 1st, ' + yyyy_s + ' - ' + yyyy_e
plotdat = vardat[var][:,:,0]
for z in range(len(zooms)):
plotfname = rundir + '/' + model + '_' + sdt + '_' + \
edt + '_apr1_' + var + '_' + \
from mpl_toolkits.basemap import Basemap, cm, shiftgrid, interp
from netCDF4 import Dataset as NetCDFFile
import numpy as N
import matplotlib.pyplot as plt
import glob
import numpy.ma as ma
from scipy.interpolate import griddata
import matplotlib.colors as colors
area = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/gridareahalf_isam.nc',
'r')
gridarea = area.variables['cell_area'][:, :]
gridlon = area.variables['lon'][:]
gridlat = area.variables['lat'][:]
gridarea, gridlon = shiftgrid(180.5, gridarea, gridlon, start=False)
#print gridlon
nclu = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/soybean_AreaYieldProduction.nc',
'r')
ncvar_maize = nclu.variables['soybeanData'][:]
latnc = nclu.variables['latitude'][:]
znc = nclu.variables['level'][:]
lonnc = nclu.variables['longitude'][:]
timenc = nclu.variables['time'][:]
latnc = N.flipud(latnc)
ncvar_maizef = N.zeros((2160, 4320))
ncvar_maizef = ncvar_maize[0, 1, :, :]
ncvar_maize1 = ncvar_maize[0, 4, :, :]
ncvar_mask = N.zeros((2160, 4320))
#-----------------INPUT VARIABLES-----------------
no_of_years = 55
season = int(sys.argv[1])
myjob = int(sys.argv[2])
#Get season name
#-----------------CALLING FUNCTION 1-----------------
season_name = seasonname()
#-----------------END CALLING FUNCTION 1-----------------
variable_name = 'psl'
datadir = '/home/scottyiu/Desktop/work/data/model/50yrs/seasonal/2D/psl/'
data = []
results = []
mydiff = np.zeros((145, 192))
el_nino_strength = [-3.0, -2.25, -1.5, -0.75, 0.0, 0.75, 1.50, 2.25, 3.0]
#We go by order of El Nino strength
data.append((NetCDFFile(datadir + variable_name + '_sea_xlnjj_' + season_name +
'_timmean.nc')))
data.append((NetCDFFile(datadir + variable_name + '_sea_xlnji_' + season_name +
'_timmean.nc')))
data.append((NetCDFFile(datadir + variable_name + '_sea_xlnjh_' + season_name +
'_timmean.nc')))
data.append((NetCDFFile(datadir + variable_name + '_sea_xlnjg_' + season_name +
'_timmean.nc')))
data.append((NetCDFFile(datadir + variable_name + '_sea_xlnja_' + season_name +
'_timmean.nc')))
data.append((NetCDFFile(datadir + variable_name + '_sea_xlnjc_' + season_name +
'_timmean.nc')))
data.append((NetCDFFile(datadir + variable_name + '_sea_xlnjd_' + season_name +
'_timmean.nc')))
data.append((NetCDFFile(datadir + variable_name + '_sea_xlnje_' + season_name +
'_timmean.nc')))
data.append((NetCDFFile(datadir + variable_name + '_sea_xlnjf_' + season_name +
filename5 = '/data/scihub-users/giyoung/PWRF_V3.6.1/RUNS/MAC_WRF/56_DeMott_WATSAT_10xHM_noThresh_eta70_MYNN/wrfout_d02_2015-11-27_00:00:00'
###################################
# Extract domain number:
###################################
domainno_start = filename1.find('/wrfout_') + 8
domainno_end = filename1.find('_2015',domainno_start)
domainno1 = filename1[domainno_start:domainno_end]
del domainno_end, domainno_start
###################################
# LOAD NETCDF FILE
###################################
nc1 = NetCDFFile(filename1, 'r')
nc2 = NetCDFFile(filename2, 'r')
nc3 = NetCDFFile(filename3, 'r')
nc4 = NetCDFFile(filename4, 'r')
nc5 = NetCDFFile(filename5, 'r')
###################################
# DEFINE TEMPERATURE BINNING
###################################
min218 = 264
max218 = 271
T3D = np.arange(np.round(min218),np.round(max218),0.2)
prams = params(T3D)
#!/usr/bin/python
# apply hierarchical clustering to output cusize based on the 'Interaction Potential'
from netCDF4 import Dataset as NetCDFFile
from matplotlib import pyplot as plt
from scipy.cluster.hierarchy import dendrogram, linkage, fcluster, ward
import numpy as np
from scipy.spatial import distance
from haversine import haversine_V
cusize = NetCDFFile('/home/vanlaar/HDCP2data/TA_dom4/cusize_output_time41.nc')
# Import data from netcdf file:
cloudlon = cusize.variables['cloud_lon']
cloudlat = cusize.variables['cloud_lat']
nclouds_cusize = cusize.variables['nclouds']
cloud_bin = cusize.variables['cloud_bin']
size = cusize.variables['size']
nclouds = int(nclouds_cusize[0])
# Adjust data format for later use:
cloud_lon = cloudlon[0, 0:nclouds]
cloud_lat = cloudlat[0, 0:nclouds]
cloud_size = cloud_bin[0, :nclouds] * size[0]
cloudcentres = np.vstack((cloud_lon, cloud_lat, cloud_size)).T
# Compute distances for all pairs based on White et al 2018:
Y = distance.pdist(cloudcentres, haversine_V)
# Compute linkage matrix:
from mpl_toolkits.basemap import Basemap, cm, shiftgrid, interp
from netCDF4 import Dataset as NetCDFFile
import numpy as N
import matplotlib.pyplot as plt
import glob
import numpy.ma as ma
from scipy.interpolate import griddata
region1 = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/HistoricalGLM_crop_150901.nc',
'r')
landfrac = region1.variables['landfrac'][:]
lonisam1 = region1.variables['lon'][:]
maitrop = region1.variables['soy_trop'][95:105, :, :]
maitemp = region1.variables['soy_temp'][95:105, :, :]
maitropi = region1.variables['soy_trop_irrig'][95:105, :, :]
maitempi = region1.variables['soy_temp_irrig'][95:105, :, :]
maitrop = ma.masked_where(maitrop <= 0, maitrop)
maitrop = ma.filled(maitrop, fill_value=0.)
maitemp = ma.masked_where(maitemp <= 0, maitemp)
maitemp = ma.filled(maitemp, fill_value=0.)
maitropi = ma.masked_where(maitropi <= 0, maitropi)
maitropi = ma.filled(maitropi, fill_value=0.)
maitempi = ma.masked_where(maitempi <= 0, maitempi)
maitempi = ma.filled(maitempi, fill_value=0.)
maizetro = maitrop + maitropi
maizetem = maitemp + maitempi
maizetor = maitrop + maitemp
maizetoi = maitropi + maitempi
from mpl_toolkits.basemap import Basemap, cm, shiftgrid,interp
from netCDF4 import Dataset as NetCDFFile
import numpy as N
import matplotlib.pyplot as plt
import glob
import numpy.ma as ma
from scipy.interpolate import griddata
from scipy.stats import ttest_ind
region1=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/RCP85_crop_150901.nc','r')
maitrop = region1.variables['soy_trop'][4,:,:]
maitemp = region1.variables['soy_temp'][4,:,:]
maitropi = region1.variables['soy_trop_irrig'][4,:,:]
maitempi = region1.variables['soy_temp_irrig'][4,:,:]
maitrop= ma.masked_where(maitrop<=0,maitrop)
maitropi= ma.masked_where(maitropi<=0,maitropi)
maitemp= ma.masked_where(maitemp<=0,maitemp)
maitempi= ma.masked_where(maitempi<=0,maitempi)
maitrop=ma.filled(maitrop, fill_value=0.)
maitropi=ma.filled(maitropi,fill_value=0.)
maitemp=ma.filled(maitemp, fill_value=0.)
maitempi=ma.filled(maitempi, fill_value=0.)
maizeto = maitrop+maitemp
maizetoi = maitropi+maitempi
maitoatemp=maitemp+maitempi
maitoatrop=maitrop+maitropi
maizetotal = maizeto+maizetoi
clm=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp85/soytrop_rcp85_constco2_rf_nofert_0.5x0.5.nc','r')
#clm=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp45/maizetrop_rcp45_co2_rf_nofert_0.5x0.5.nc','r')
#clm=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp45/maizetrop_rcp45_co2_rf_fert_0.5x0.5.nc','r')
#clm=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp45/maizetrop_rcp45_co2_irrig_fert_0.5x0.5.nc','r')
from mpl_toolkits.basemap import Basemap, cm, shiftgrid, interp
from netCDF4 import Dataset as NetCDFFile
import numpy as N
import matplotlib.pyplot as plt
import glob
import numpy.ma as ma
from scipy.interpolate import griddata
import matplotlib.colors as colors
from statsmodels.stats.weightstats import DescrStatsW
from scipy.stats import ttest_ind
from matplotlib.markers import TICKDOWN
import matplotlib.patches as mpatches
area = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/gridareahalf_isam.nc',
'r')
gridarea = area.variables['cell_area'][:, :]
gridlon = area.variables['lon'][:]
gridlat = area.variables['lat'][:]
gridarea, gridlon1 = shiftgrid(180.5, gridarea, gridlon, start=False)
#print gridlon
nclu = NetCDFFile(
'/scratch2/scratchdirs/tslin2/plot/globalcrop/data/m3yield_isam.nc', 'r')
ncvar_maize = nclu.variables['maize_total'][0, :, :]
ncvar_soy = nclu.variables['soy_total'][0, :, :]
areamaize = nclu.variables['maize_area'][0, :, :]
areasoy = nclu.variables['soy_area'][0, :, :]
latnc = nclu.variables['lat'][:]
lonnc = nclu.variables['lon'][:]
ncvar_maize, gridlon1 = shiftgrid(180.5, ncvar_maize, gridlon, start=False)
return clmy,areall,clmall
areaa= N.zeros((115, 360, 720))
yiep= N.zeros((115, 360, 720))
yief= N.zeros((115, 360, 720))
years = range(1901, 2016)
for i, yeara in enumerate(years):
yie=yieldout(yeara)
yief[i, :, :] = yie[0]
areaa[i,:,:]=yie[1]
yiep[i,:,:]=yie[2]
area=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/gridareahalf_isam.nc','r')
gridarea = area.variables['cell_area'][:,:]
gridlon = area.variables['lon'][:]
gridlat=area.variables['lat'][:]
gridarea,gridlon = shiftgrid(180.5,gridarea,gridlon,start=False)
#print gridlon
gg= N.zeros((115, 360, 720))
for i in range(0,115):
gg[i,:,:]=gridarea[:,:]
yiey=yiep/(gg*0.0001)
ncfile=NetCDFFile('isamhiscru_soy_luh2.nc','w',format='NETCDF3_64BIT_OFFSET')
ncfile.createDimension('lat', 360)
ncfile.createDimension('lon', 720)
ncfile.createDimension('time', 115)
def draw_velocity_map_with_level(nc_file_name, level):
nc = NetCDFFile(nc_file_name, 'r+')
lat = nc.variables['nav_lat_grid_U'][:]
lon = nc.variables['nav_lon_grid_U'][:]
velocity = np.zeros((400, 1100), dtype=np.float32)
time = 0
x_vel = nc.variables['vozocrtx'][:][time][level]
y_vel = nc.variables['vomecrty'][:][time][level]
velocity = data.calculate_velocity_magnitude_matrix(x_vel, y_vel)
lat_left_bottom = lat[-1][-1]
lon_left_bottom = lon[-1][-1]
lat_right_top = lat[0][0]
lon_right_top = lon[0][0]
lat_center = 90
# 110, 119
lon_center = 110
m = Basemap(projection='stere',
lon_0=lon_center,
lat_0=lat_center,
resolution='l',
llcrnrlat=lat_left_bottom,
llcrnrlon=lon_left_bottom,
urcrnrlat=lat_right_top,
urcrnrlon=lon_right_top)
m.pcolormesh(lon, lat, velocity, latlon=True, cmap='jet', vmax=0.6)
m.drawcoastlines()
m.drawcountries()
m.fillcontinents(color='#cc9966', lake_color='#99ffff')
plt.colorbar()
plt.title(nc_file_name)
model = load_model("samples/model.h5")
for y in range(0, 400, 100):
for x in range(0, 1100, 100):
sample = np.zeros((1, 100, 100, 1), dtype=np.float32)
sample[0] = np.expand_dims(velocity[y:y + 100, x:x + 100], axis=2)
# print(sample)
result = model.predict(sample)
result_x, result_y = m(lon[y + 50][x + 50], lat[y + 50][x + 50])
max_x, max_y = m(lon[y + 70][x + 50], lat[y + 70, x + 50])
plt.text(result_x,
result_y,
str(result[0][0]),
ha='center',
size=10,
color="yellow",
bbox=dict(facecolor='black', alpha=0.5,
edgecolor='black'))
plt.text(max_x,
max_y,
np.max(sample[0]),
ha='center',
size=10,
color="yellow")
if result[0][0] > 0.5:
lat_poly = np.array([
lat[y][x], lat[y][x + 99], lat[y + 99][x + 99],
lat[y + 99][x]
])
lon_poly = np.array([
lon[y][x], lon[y][x + 99], lon[y + 99][x + 99],
lon[y + 99][x]
])
mapx, mapy = m(lon_poly, lat_poly)
points = np.zeros((4, 2), dtype=np.float32)
for j in range(0, 4):
points[j][0] = mapx[j]
points[j][1] = mapy[j]
poly = Polygon(points, facecolor='green', alpha=0.4)
plt.gca().add_patch(poly)
plt.show()
def yieldout(year):
bb=year-1900
bb1=year-850
region1=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/luh2area_850_2015_corrcrop.nc','r')
maitrop1 = region1.variables['fsoy_rf'][bb1,:,:]
maitropi1=region1.variables['fsoy_irr'][bb1,:,:]
maitrop1=ma.masked_where(maitrop1<=0,maitrop1)
maitrop1=ma.filled(maitrop1, fill_value=0.)
maitropi1=ma.masked_where(maitropi1<=0,maitropi1)
maitropi1=ma.filled(maitropi1, fill_value=0.)
lonisam=region1.variables['lon'][:]
maitrop,lonisam1 = shiftgrid(180.5,maitrop1,lonisam,start=False)
maitropi,lonisam1 = shiftgrid(180.5,maitropi1,lonisam,start=False)
maizetor=maitrop
maizetoi=maitropi
maizetrop=maitrop+maitropi
maizeto = maitrop+maitropi
isam=NetCDFFile('/scratch2/scratchdirs/tslin2/isam/maisoy_cheyenne/his_cru/soy_fert/output/soy_fert.nc','r')
clmtropf = isam.variables['totalyield'][bb-1,:,:]
clm2=NetCDFFile('/scratch2/scratchdirs/tslin2/isam/maisoy_cheyenne/his_cru/soy_irr_fert/output/soy_irr_fert.nc','r')
clmtropfi = clm2.variables['totalyield'][bb-1,:,:]
lonisam=clm2.variables['lon'][:]
clmtropf,lonisam1 = shiftgrid(180.5,clmtropf,lonisam,start=False)
clmtropfi,lonisam1 = shiftgrid(180.5,clmtropfi,lonisam,start=False)
print lonisam1
clmtropf= ma.masked_where(maitrop<=0,clmtropf)
clmtropf=ma.filled(clmtropf, fill_value=0.)
clmtropfi= ma.masked_where(maitropi<=0,clmtropfi)
clmtropfi=ma.filled(clmtropfi, fill_value=0.)
yield_clmtf=clmtropf
yield_clmtf = ma.masked_where(yield_clmtf<=0,yield_clmtf)
yield_clmtf=ma.filled(yield_clmtf, fill_value=0.)
yield_clmtfi=clmtropfi
yield_clmtfi = ma.masked_where(yield_clmtfi<=0,yield_clmtfi)
yield_clmtfi=ma.filled(yield_clmtfi, fill_value=0.)
area=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/gridareahalf_isam.nc','r')
gridarea = area.variables['cell_area'][:,:]
gridlon = area.variables['lon'][:]
gridlat=area.variables['lat'][:]
gridarea,gridlon = shiftgrid(180.5,gridarea,gridlon,start=False)
lon2,lat2 = N.meshgrid(gridlon,gridlat)
map = Basemap(projection ='cyl', llcrnrlat=-65, urcrnrlat=90,llcrnrlon=-180, urcrnrlon=180, resolution='c')
x,y = map(lon2,lat2)
yield_clmtf=maskoceans(x,y,yield_clmtf)
yield_clmtf = ma.masked_where(maizeto<=0,yield_clmtf)
yield_clmtfi=maskoceans(x,y,yield_clmtfi)
yield_clmtfi = ma.masked_where(maizeto<=0,yield_clmtfi)
clmy=((yield_clmtf*maizetor)+(yield_clmtfi*maizetoi))/((maizetoi)+(maizetor))
areall=(maizetoi)+(maizetor)
clmall=((yield_clmtf*maizetor)+(yield_clmtfi*maizetoi))
return clmy,areall,clmall
11.05.2016 """ from netCDF4 import Dataset as NetCDFFile from mpl_toolkits.basemap import Basemap import matplotlib.pyplot as plt import numpy as np # Fontsize font = 15 wrf_path = '/global/work/blasterdalen/WRF_Dec/wrfout_d03_2014-12-10_00:00:00' geo_path = '/home/blasterdalen/Ymse/geo_em.d03.nc' nc_wrf = NetCDFFile(wrf_path, mode='r') nc_geo = NetCDFFile(geo_path, mode='r') # Extracting 3-D variables (time, south-north, west-east) from WRF time = 72 # time of interest lon = nc_wrf.variables['XLONG'][time,:,:] lat = nc_wrf.variables['XLAT'][time,:,:] # 4-D variables (time, eta, lon, lat) eta = 4 # index of 4 gives (normally) height 60 meter a.g.l. u = nc_wrf.variables['U'][time,eta,0:300,0:300] v = nc_wrf.variables['V'][time,eta,0:300,0:300] # Extracting top. height from geo-file lon_geo = nc_geo.variables['XLONG_M'][0,:,:] lat_geo = nc_geo.variables['XLAT_M'][0,:,:] hgt = nc_geo.variables['HGT_M'][0,:,:]
from mpl_toolkits.basemap import Basemap, cm, shiftgrid,interp
from netCDF4 import Dataset as NetCDFFile
import numpy as N
import matplotlib.pyplot as plt
import glob
import numpy.ma as ma
from scipy.interpolate import griddata
from scipy.stats import ttest_ind
region1=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/RCP85_crop_150901.nc','r')
maitrop = region1.variables['maize_trop'][4,:,:]
maitemp = region1.variables['maize_temp'][4,:,:]
maitropi = region1.variables['maize_trop_irrig'][4,:,:]
maitempi = region1.variables['maize_temp_irrig'][4,:,:]
maitrop= ma.masked_where(maitrop<=0,maitrop)
maitropi= ma.masked_where(maitropi<=0,maitropi)
maitemp= ma.masked_where(maitemp<=0,maitemp)
maitempi= ma.masked_where(maitempi<=0,maitempi)
maitrop=ma.filled(maitrop, fill_value=0.)
maitropi=ma.filled(maitropi,fill_value=0.)
maitemp=ma.filled(maitemp, fill_value=0.)
maitempi=ma.filled(maitempi, fill_value=0.)
maizeto = maitrop+maitemp
maizetoi = maitropi+maitempi
maitoatemp=maitemp+maitempi
maitoatrop=maitrop+maitropi
maizetotal = maizeto+maizetoi
#clm=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp85/maizetrop_rcp85_constco2_rf_nofert_0.5x0.5.nc','r')
#clm=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp85/maizetrop_rcp85_co2_rf_nofert_0.5x0.5.nc','r')
#clm=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp85/maizetrop_rcp85_co2_rf_fert_0.5x0.5.nc','r')
clm=NetCDFFile('/scratch2/scratchdirs/tslin2/plot/globalcrop/data/clm/clm45rcp85/maizetrop_rcp85_co2_irrig_fert_0.5x0.5.nc','r')
