コード例 #1
0
    print ' ... OBS  ...',  obs.shape, '\n'

    outdir = '{0}{1}-{2}'.format(fcst_month, fcst_year, hind_period)
    if not os.path.exists(outdir):
        os.makedirs(outdir)

    print " === OUTPUT DIR: {0} ===\n".format(outdir)

    # Limites do mapa para fazer o plot
    # y1, y2, x1, x2 = -40., 40., -150., 70.  # Globo
    #~ y1, y2, x1, x2 = -89., 89., -178., 178.  # Globo
    #~ y1, y2, x1, x2 = -23., 9., -75., -34.  # Região Reliability
    y1, y2, x1, x2 = -60., 15., -90., -30.  # América do sul

    ###########  CORRELAÇÃO  ###########
    correl = cs.compute_pearson(hind, obs, n_years)
    figtitle = u'ECHAM4.6 x CMAP - {0}/{1} ({2})\nCorrelação - Precip Acum'.format(fcst_month_name, target_months, hind_period_name)
    #~ figtitle = u'ECHAM4.6 x CMAP - {0}/{1} ({2})\nCorrelation - Precip Accum'.format(fcst_month_name, target_months, hind_period_name)
    figname = "{3}/bra_precip_persistida_{0}_null-{1}_null_{2}_echam46_1dg_cmap_correlacao.png".format(hind_period_name, target_months, n_fcst_month, outdir)
    levs = (-1.0, -0.9, -0.7, -0.5, -0.3,
             0.3,  0.5,  0.7,  0.9,  1.0) #10
    my_colors = ('#2372c9', '#3498ed', '#4ba7ef', '#76bbf3', '#93d3f6',
                 '#b0f0f7', '#ffffff', '#fbe78a', '#ff9d37', '#ff5f26',
                 '#ff2e1b', '#ff0219', '#ae000c') #13
    pm.plotmap(correl, newlats-1./2., newlons-1./2., latsouthpoint=y1, latnorthpoint=y2,
        lonwestpoint=x1, loneastpoint=x2, fig_name=figname, barloc='right',
        barcolor=my_colors, barlevs=levs, fig_title=figtitle, barinf='neither', ocean_mask=1)
    background = Image.open(figname)
    foreground = Image.open("FUNCEME_LOGO.png")
    foreground = foreground.resize((90, 70), Image.ANTIALIAS)
    background.paste(foreground, (334, 461), foreground)
コード例 #2
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    print 'lons:', obs_lons

    outdir = '{0}{1}-{2}-rsm97'.format(fcst_month, fcst_year, hind_period)
    if not os.path.exists(outdir):
        os.makedirs(outdir)

    print " === OUTPUT DIR: {0} ===\n".format(outdir)

    # Limites do mapa para fazer o plot
    # y1, y2, x1, x2 = -40., 40., -150., 70.  # Globo
    #~ y1, y2, x1, x2 = -89., 89., -178., 178.  # Globo
    #~ y1, y2, x1, x2 = -23., 9., -75., -34.  # Região Reliability
    y1, y2, x1, x2 = -21.3, 7., -55.6, -34  # América do sul

    ###########  CORRELAÇÃO  ###########
    correl = cs.compute_pearson(hind, obs, n_years)
    figtitle = u'RSM97 x UTEXAS - {0}/{1} ({2})\nCorrelação - Precip Acum'.format(fcst_month_name, target_months, hind_period_name)
    figname = "{3}/bra_precip_persistida_{0}_null-{1}_null_{2}_rsm97_1dg_utexas_correlacao.png".format(hind_period_name, target_months, n_fcst_month, outdir)
    levs = (-1.0, -0.9, -0.7, -0.5, -0.3,
             0.3,  0.5,  0.7,  0.9,  1.0) #10
    my_colors = ('#2372c9', '#3498ed', '#4ba7ef', '#76bbf3', '#93d3f6',
                 '#b0f0f7', '#ffffff', '#fbe78a', '#ff9d37', '#ff5f26',
                 '#ff2e1b', '#ff0219', '#ae000c') #13
    pm.plotmap(correl, obs_lats-0.54/2., obs_lons-0.54/2., latsouthpoint=y1, latnorthpoint=y2,
        lonwestpoint=x1, loneastpoint=x2, fig_name=figname, barloc='right',
        barcolor=my_colors, barlevs=levs, fig_title=figtitle, barinf='neither', ocean_mask=1)
    background = Image.open(figname)
    foreground = Image.open("/home/marcelo/FSCT-ECHAM46/FUNCEME_LOGO.png")
    foreground = foreground.resize((90, 70), Image.ANTIALIAS)
    background.paste(foreground, (313, 460), foreground)
    background.save(figname, optimize=True, quality=95)
コード例 #3
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    #           '_echam46_1dg_null_precip.png'.format(hind_period_name,
    #           target_year, target_months, fcst_year, n_fcst_month, outdir)
    # pm.plotmap(fcst[0, :, :], newlats, newlons, latsouthpoint=-88.,
    #            latnorthpoint=88., lonwestpoint=-178., loneastpoint=178.,
    #            fig_name=figname, fig_title=figtitle, barcolor=my_colors,
    #            ocean_mask=0, barlevs=lev, barinf='max', barloc='bottom',
    #            meridians=np.arange(-160., 161., 30.),
    #            parallels=np.arange(-90., 91., 20.))

    if obs_base == 'cmap':

        ###  Anomalia corrigida metódo do Caio (regressão linear)  ###
        # below, normal, above, f_signal, f_std, o_pad, fcst_sig_anom = \
        # cs.compute_probability(fcst, hind, obs, n_years)
        below, normal, above, f_signal, f_std, o_pad, fcst_sig_anom = \
        cs.compute_probability(fcst, hind, obs)

        hind_corrigido = cs.compute_setrighthind(hind, obs)

        anomaly_corrigida, anomaly_pad = \
        cs.compute_anomaly(fcst_sig_anom, hind_corrigido)

        figtitle = u'ECHAM4.6 x CMAP - {0}/{3} - {1}/{4}\nAnomalia (mm)' \
                   ' - Precip Acum ({2})'.format(fcst_month_name,
                   target_months, hind_period_name, fcst_year, target_year)

        figname_anom = '{5}/bra_precip_persistida_{0}_{1}-{2}_{3}_{4}_' \
                       'echam46_1dg_null_anom.png'.format(hind_period_name,
                       target_year, target_months, fcst_year,
                       n_fcst_month, outdir)
コード例 #4
0
ファイル: run.py プロジェクト: marcelorodriguesss/FCST
        # Observado
        pcp_obs_ce = obs_file['pcp'][:, 29:31, 114]
        obs_ce = np.asarray(pcp_obs_ce)

        # Média sobre o CE
        fsct_aux_ce = np.apply_over_axes(np.mean, fsct_ce, [1, 2])
        hind_aux_ce = np.apply_over_axes(np.mean, hind_ce, [1, 2])
        obs_aux_ce = np.apply_over_axes(np.mean, obs_ce, [1, 2])

        outdir = "%s%s_HIND%s" % (fcst_month.upper(), fcst_year, hind_period)
        if not os.path.exists(outdir):
            os.makedirs(outdir)

        # Curva de probabilidade para o CE
        figname = outdir + '/' + 'prob_echam46_issue_%s%s_target_%s%s_%s_curve_ce.png' % (fcst_month, fcst_year, target_months, target_year, hind_period)
        below_ce, normal_ce, above_ce, f_signal_ce, f_std_ce, o_pad_ce = cs.compute_probability(fsct_aux_ce[:, 0, 0], hind_aux_ce[:, 0, 0], obs_aux_ce[:, 0, 0])
        pm.plotnorm(f_signal_ce, f_std_ce, o_pad_ce, fig_name=figname, fig_title='')

        ### Fim Bloco Curva para o CE ###


        # Tercil mais provável para toda a região do globo
        file_out = outdir + '/' + "prob_echam46_issue_%s%s_target_%s%s_%s.nc" % (fcst_month, fcst_year, target_months, target_year, hind_period)
        below, normal, above, f_signal, f_std, o_pad = cs.compute_probability(fsct, hind, obs)
        cn.create_netcdf_probs(below, normal, above, lats, lons, fileout=file_out)
        # ferret_command = "/home/marcelo/pyferret-0.0.9/bin/pyferret.sh -nojnl -gif -script plot_tercis_ensemble.jnl {0}".format(file_out)
        # os.system(ferret_command)

        # Correlacao
        correl = cs.corr_pearson(hind, obs)
コード例 #5
0
lats = obs_data.variables['lat'][:]
obs_data.close()
pcp_obs = np.mean(pcp_obs, axis=0)
# pcp_obs_aux, lons_obs_aux = shiftgrid(180., pcp_obs, lons, start=False)


obs_path = "/Users/Hulk/clim-verification/CMAP/CMAP89-08-FMA-T42.nc"
clim_obs_path = "/Users/Hulk/obs_pcp/cmap/cmap.merge.funceme.precip.standard.FMA.season.accum.1dg.nc"
clim_obs_data = pupynere.NetCDFFile(clim_obs_path, 'r')
print clim_obs_data.variables
clim_pcp_obs = clim_obs_data.variables['precip'][:]
print clim_pcp_obs.shape
clim_obs_data.close()
# clim_pcp_obs_aux, lons_clim_aux = shiftgrid(180., clim_pcp_obs, lons, start=False)

mytercis, tercilinf, tercilupp = cs.tercil_verification(clim_pcp_obs, pcp_obs)
print mytercis.shape

lons -= 1./2.
lats -= 1./2.

# Plot precip acumulada
lev = [0., 50., 100., 200., 300., 500., 700., 900., 1000.]
my_colors = ('#CC3333', '#FF6633', '#FF9933', '#FFFF99', '#FFFFCC', '#CCFFCC', '#99FFCC', '#66FF66', '#00CC00', '#009900', '#003300') #11
pm.map_shaded(pcp_obs, lats, lons,
              meridians=np.arange(-160., 161., 10.),
              fig_name="cmap.merge.funceme.fma.2015.accum.1dg.png", barlevs=lev, barcolor=my_colors,
              latsouthpoint=-60., latnorthpoint=15., fig_title="CMAP/FUNCEME - FMA 2015 - ACUM",
              lonwestpoint=-90., loneastpoint=-30., barinf="max", ocean_mask=1)

コード例 #6
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# clim_obs_path = "/Users/Hulk/FSCT-ECHAM46/obs_data/cmap/CMAP.glb.89-08-FMA-1.0dg.nc"
clim_obs_path = "/Users/Hulk/obs_pcp/cmap.precip.mean.enhanced.1989-2008.FMA.nc3.nc"
clim_obs_data = pupynere.NetCDFFile(clim_obs_path, 'r')
# clim_pcp_obs = clim_obs_data.variables['pcp'][:]
clim_pcp_obs = clim_obs_data.variables['PRECIP'][:]
clim_obs_data.close()

# exit()

# pcp_obs = np.mean(pcp_obs, axis=0)
# pcp_obs = pcp_obs * 89. # Fev 28, Mar 31, Abr 30

pcp_obs = pcp_obs * 89
clim_pcp_obs = clim_pcp_obs * 89

mytercis = cs.tercil_verification(clim_pcp_obs, pcp_obs)

# Plot categorias
lev = [-1, 0., 1., 2.]
my_colors = ('#F75026', '#57F255', '#4143F2')
pm.map_shaded(mytercis, lats-1./2., lons-1./2.,
              meridians=np.arange(-160., 161., 10.),
              fig_name="cmap.fma.2015.cat.png", barlevs=lev, barcolor=my_colors,
              latsouthpoint=-60., latnorthpoint=15., fig_title="CMAP - FMA 2015 - CAT",
              lonwestpoint=-90., loneastpoint=-30., ocean_mask=1)

# Plot precip acumulada
lev = [0., 50., 100., 200., 300., 500., 700., 900., 1000.]
my_colors = ('#CC3333', '#FF6633', '#FF9933', '#FFFF99', '#FFFFCC', '#CCFFCC', '#99FFCC', '#66FF66', '#00CC00', '#009900', '#003300') #11
pm.map_shaded(pcp_obs, lats-1./2., lons-1./2.,
              meridians=np.arange(-160., 161., 10.),
コード例 #7
0
ファイル: run-nmme.py プロジェクト: marcelorodriguesss/FCST
obs = obs_file.variables['pcp'][:, :, :]
# obs_ce = obs_file.variables['pcp'][:, 53:58, 49:53]
# obs_mean_ce = np.apply_over_axes(np.mean, obs_ce, [1, 2])

# obs_ce = obs_file.variables['pcp'][:, 52:54, 51:53]
# obs_mean_ce = np.apply_over_axes(np.mean, obs_ce, [1, 2])
obs_ce = obs_file.variables['pcp'][:, 52:53, 53:54]
obs_mean_ce = np.apply_over_axes(np.mean, obs_ce, [1, 2])

# Longitude e latitude
lons = fsct_file.variables['lon'][:]
lats = fsct_file.variables['lat'][:]


# Curva de probabilidade
below_ce, normal_ce, above_ce, f_signal_ce, f_std_ce, o_pad_ce = cm.compute_probability(fsct[:, 0, 0], hind[:, 0, 0], obs[:, 0, 0])
pm.plotnorm(f_signal_ce, f_std_ce, o_pad_ce, fig_name='prob.echam46+nmme.curve.ce.png', fig_title='')

# below, normal, above, f_signal, f_std, o_pad = cm.compute_probability(fsct, hind, obs)
# cn.create_netcdf_probs(below, normal, above, lats, lons, fileout="prob_nmme+echam46_issue_jan2015_target_fma2015.nc")

# Anomalia
# anomaly, anomaly_pad = cm.compute_anomaly(fsct, hind)

# Shift na longitude e nos dados do modelo
# Isso é necessário pois a longitude do NetCDF é no formato 0 - 360
# a função aceita valores de longitude no formato -180 - +180
# Chefinho quer ver todos os oceanos
# anomaly, fsct_lon = shiftgrid(30., anomaly, fsct_lon, start=False)
# anomaly, lons_anom_aux = shiftgrid(180., anomaly, lons, start=False)
コード例 #8
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def compute_reliability(model, obs, lentime):

    '''
    Salva um arquivo com a verificação dos tercis mais prováveis comparando o modelado com o observado
    Os arrays model e obs tem que ter o mesmo shape
    :param model: numpy.Array do dado modelado
    :param obs: numpy.Array do dado observado
    :param path_saida: Caminho/Nome do arquivo txt de saida.
    :return: arquivo de verificação
    '''

    try:
        if type(model).__module__ != np.__name__:
            raise ValueError('A variável "model" não é do tipo numpy array!!!')
        elif type(obs).__module__ != np.__name__:
            raise ValueError('A variável "obs" não é do tipo numpy array!!!')

        elif model.shape != obs.shape:
            raise Exception('Os arrays não possuem o mesmo shape!!!')

    except ValueError:
        print '===> Atenção na entrada dos np.arrays:'
        raise

    except Exception:
        print '===> Cheque o shape dos arrays'
        raise

    pcp_masked = np.ma.array(obs)  # transforma num masked array para retirar a mascara

    mask_obs = pcp_masked.mask

    if mask_obs:
        pcp_nan = np.where(mask_obs, np.NaN,obs)
    else:
        pcp_nan = obs

    xlow = 1./3.*100
    xup = 2./3.*100

    pcp_low = np.percentile(pcp_nan, xlow, axis=0)
    pcp_up = np.percentile(pcp_nan, xup, axis=0)

    #~ path_below = ''.join((path_saida.split(".")[0], "_below.", path_saida.split(".")[-1]))
    #~ path_normal = ''.join((path_saida.split(".")[0], "_normal.", path_saida.split(".")[-1]))
    #~ path_above = ''.join((path_saida.split(".")[0], "_above.", path_saida.split(".")[-1]))

    path_below = "reliability_below.txt"
    path_normal = "reliability_normal.txt"
    path_above = "reliability_above.txt"

    f_verifc_below = open(path_below, 'w')
    f_verifc_normal = open(path_normal, 'w')
    f_verifc_above = open(path_above, 'w')

    for i in range(0, obs.shape[0]):

        p_below, p_normal, p_above, fcst_signal, fcst_std, obs_pad, dummy =\
             cs.compute_probability(model[i], model, pcp_nan, lentime)

        p_below, p_normal, p_above = p_below/100., p_normal/100., p_above/100.

        obs_below = (obs[i, :, :] < pcp_low)
        obs_normal = ((obs[i, :, :] >= pcp_low) & (obs[i, :, :] <= pcp_up))
        obs_above = (obs[i, :, :] > pcp_up)

        for j in range(0,obs.shape[1]):

            for k in range(0,obs.shape[2]):

                if obs_below[j,k] == True:
                    f_verifc_below.write("{0} {1} \n".format(p_below[j,k], 1))
                else:
                    f_verifc_below.write("{0} {1} \n".format(p_below[j,k], 0))

                if obs_normal[j,k] == True:
                    f_verifc_normal.write("{0} {1} \n".format(p_normal[j,k], 1))
                else:
                    f_verifc_normal.write("{0} {1} \n".format(p_normal[j,k], 0))

                if obs_above[j,k] == True:
                    f_verifc_above.write("{0} {1} \n".format(p_above[j,k], 1))
                else:
                    f_verifc_above.write("{0} {1} \n".format(p_above[j,k], 0))
コード例 #9
0
above = np.loadtxt("echam46_above.txt")
normal = np.loadtxt("echam46_normal.txt")
below = np.loadtxt("echam46_below.txt")

print "\n => Plot diagram...\n"

mytitle = "Diagrama de atributos: {2}/{1} - ({0})".format(hind_period, target_months, fcst_month)
figura, ax = plot_reliability(below[:,0], below[:,1], maintitle=mytitle, cor='blue')
figura, ax = plot_reliability(normal[:,0], normal[:,1], maintitle=mytitle, first=False, fig=figura, cor='y')
figura, ax = plot_reliability(above[:,0], above[:,1], maintitle=mytitle, first=False, fig=figura, cor='red')
name_fig = "bra_precip_persistida_{0}_null-{1}_null_{2}_echam46_1dg_cmap_reliability.png".format(hind_period, target_months, n_fcst_month)
plt.savefig(name_fig)
plt.close()


correl = cs.compute_pearson(pcp_model, pcp_obs, timelen=14.)

# correl_aux, lons_aux = shiftgrid(180., correl, lons, start=False)

figtitle = u'RSM97 x PRECL - FMA - 02-15\nPersistida - 0.54x0.54 - Correlação - Precip Acum'

figname = "correl_rsm97per_x_precl_jfm_0215.png"

levs = (-1.0, -0.9, -0.7, -0.5, -0.3,
         0.3,  0.5,  0.7,  0.9,  1.0) #10

my_colors = ('#2372c9', '#3498ed', '#4ba7ef', '#76bbf3', '#93d3f6',
             '#b0f0f7', '#ffffff', '#fbe78a', '#ff9d37', '#ff5f26',
             '#ff2e1b', '#ff0219', '#ae000c') #13

print "\n... salvando figura ..."
コード例 #10
0
ファイル: map_tercis.py プロジェクト: marcelorodriguesss/FCST
from PyFuncemeClimateTools import PlotMaps as pm
from PyFuncemeClimateTools import CreateNetCDF as cn
from read_data import read_data


pcp, pcpe, obs = read_data()

nla = np.linspace(-90., 90., 181)

nlo = np.linspace(-180., 179., 360)

x, y = np.meshgrid(nlo, nla)

y1, y2, x1, x2 = -60., 15., -90., -30.

correl = cs.compute_pearson(pcp[0:30, :, :], obs[0:30, :, :])

figtitle = u'ECHAM4.6 x CMAP - {0}/{1} ({2})\nCorrelação - Precip Acum' \
           .format('JAN', 'FMA', '8110')

if not os.path.exists('figs_expsolar/map_correl'):
    os.makedirs('figs_expsolar/map_correl')

figname = 'figs_expsolar/map_correl' \
          '/bra_precip_persistida_{0}_null-{1}_null_{2}_echam46_1dg_cmap_' \
          'correlacao.png' \
          .format('8110', 'FMA', 'JAN')

levs = (-1.0, -0.9, -0.7, -0.5, -0.3, 0.3, 0.5, 0.7, 0.9, 1.0)  # 10

my_colors = ('#2372c9', '#3498ed', '#4ba7ef', '#76bbf3', '#93d3f6',
コード例 #11
0
    figname = "img/curve_prob_{0}_{1}_{2}_{3}_{4}_{5}_{6}_{7}.png".format(
        mylon, mylat, myopt, myhind, myfmon, mytseason, myfyear, mytyear
    )

    # Se a imagem nao tiver sido gerada anteriomente
    if not os.path.exists(figrealname):

        print "entrooou... delicia! =)"

        fcst, hind, obs = readdata(myhind, myfmon, myfyear, mytyear, mytseason)

        if not os.path.exists("img"):
            os.makedirs("img")

        below, normal, above, fsignal, fstd, opad, fs_anom = cs.compute_probability(
            fcst[0, i_lat, i_lon], hind[:, i_lat, i_lon], obs[:, i_lat, i_lon], lenhind
        )

        fsignal = np.expand_dims(fsignal, axis=0)

        pm.plotnorm(fsignal, fstd, opad, fig_name=figname, fig_title="")

        shutil.copy2(figname, figrealname)

    else:

        print "nao entrou =("

        # se a imagem ja tiver sido gerada, apenas faz copia para exibir no site
        shutil.copy2(figrealname, figname)
コード例 #12
0
    print "Erro ao ler arquivo do hindcast"
    exit()

# Arquivo observação
try:
    obs_file = "cmap.{0}-{1}-1.0dg.fix.nc".format(hind_period, target_months)
    read_obs_file = pupynere.NetCDFFile(obs_file, 'r')
    obs = read_obs_file.variables['pcp'][:, :, :]
    read_obs_file.close()
except:
    print "Erro ao ler arquivo observado"
    exit()

# RMSE
print "... RMSE ..."
error_rmse = cs.rmse(hind, obs)
rmse_title = u'ECHAM4.6 x CMAP - {0}/{1} ({2})\nRMSE (mm) - Precip Acum'.format(fcst_month, target_months, hind_period)
fig_rmse = 'bra_precip_persistida_{0}_null-{1}_null_{2}_echam46_1dg_cmap_rmse.png'.format(hind_period, target_months, n_fcst_month)
levs = (0., 50., 100., 200., 400., 600., 800.) #7
my_colors = ('#ffffff', '#E1FFFF', '#B4F0FA', '#96D2FA', '#78B9FA', 
             '#50A5F5', '#3C96F5', '#2882F0') #8
pm.map_shaded(error_rmse, lats-1./2., lons-1./2., latsouthpoint=-60., latnorthpoint=15., 
    lonwestpoint=-90., loneastpoint=-30.,  fig_name=fig_rmse, barloc='right', 
    barcolor=my_colors, barlevs=levs, fig_title=rmse_title, barinf='max', ocean_mask=1)

# Desvio padrão
print u"... desvio padrão ..."
hind_std = np.nanstd(hind, axis=0)
hind_std_title = u'ECHAM4.6 x CMAP - {0}/{1} ({2})\nDesvio Padrão (mm) - Precip Acum'.format(fcst_month, target_months, hind_period)
fig_hind_std = 'bra_precip_persistida_{0}_null-{1}_null_{2}_echam46_1dg_cmap_std.png'.format(hind_period, target_months, n_fcst_month)
levs = (0., 25., 50., 75., 100., 150., 200.) #7
コード例 #13
0

# Carrega arquivo da climatologia
clim_file = Dataset('/Users/Hulk/TestPyFuncemeClimateTools/lib/python2.7/site-packages/PyFuncemeClimateTools/examples/pcp-daily-total-ec4amip_8908JFM.nc')
clim_pcp = clim_file.variables['pcp'][:]

# Carrega arquivo da previsão
fsct_file = Dataset('/Users/Hulk/TestPyFuncemeClimateTools/lib/python2.7/site-packages/PyFuncemeClimateTools/examples/pcp-daily-total-ec4amip_2015JFM.nc')
fsct_pcp = fsct_file.variables['pcp'][:]

# Longitude e latitudes
fsct_lon = fsct_file.variables['longitude'][:]
fsct_lat = fsct_file.variables['latitude'][:]

# Calcula anomalias
# A função abaixo retornar dois parametros
myanom, myanom_pad = cs.compute_anomaly(fsct_pcp, clim_pcp)

# Shift na longitude e nos dados do modelo
# Isso é necessário pois a longitude do NetCDF é no formato 0 - 360
# a função aceita valores de longitude no formato -180 - +180
myanom, fsct_lon = shiftgrid(180., myanom, fsct_lon, start=False)

# Plot map
# a variavel a ser plotada deve ser 2d
pm.anom_map_shaded(myanom[0, :, :], fsct_lon-2.8125/2., fsct_lat-2.8125/2.)




コード例 #14
0
# lons = read_fcst_file.variables['lon'][:]
# read_fcst_file.close()

# hind_file = "/home/marcelo/FSCT-ECHAM46/APR2015_HIND89-08-1DG/pcp-daily-total-ec4amip_89-08MJJ.1.0dg.fix.nc"
# read_hind_file = pupynere.NetCDFFile(hind_file, 'r')
# hind = read_hind_file.variables['pcp'][:, :, :]
# read_hind_file.close()
#
# obs_file = "/home/marcelo/FSCT-ECHAM46/APR2015_HIND89-08-1DG/cmap.89-08-MJJ-1.0dg.fix.nc"
# read_obs_file = pupynere.NetCDFFile(obs_file, 'r')
# obs = read_obs_file.variables['pcp'][:, :, :]
# read_obs_file.close()

if myopt == "p":
    n_lon, n_lat, i_lon, i_lat = dg.gridpoint(lons, lats, mylon, mylat)
    myfcst = fsct[0, i_lat, i_lon]
    myhind = hind[:, i_lat, i_lon]
    myobs = obs[:, i_lat, i_lon]
    below, normal, above, fsignal, fstd, opad = cs.compute_probability(myfcst, myhind, myobs)
    fsignal = np.expand_dims(fsignal, axis=0)
    figname = "curve_prob_%s_%s.png" % (mylon, mylat)
    pm.plotnorm(fsignal, fstd, opad, fig_name=figname, fig_title='')

elif myopt == "a":
    print 't1'
    pass

else:
    print 't2'
    pass
コード例 #15
0
obs_aux = obs_file.variables['pre'][:]
lons_obs = obs_file.variables['lon'][:]
lats_obs = obs_file.variables['lat'][:]
obs_file.close()

x, y = np.meshgrid(lons_hind, lats_hind)

# Interpola hindcast
obs = np.full((30, 110, 129), np.nan)
for i in range(30):
    obs[i, ...] = interp(obs_aux[i, ...], lons_obs, lats_obs, x, y, order=1)

print(obs.shape)

###########  CORRELAÇÃO  ###########
correl = cs.compute_pearson(hind, obs)
figtitle = u'RSM2008 x INMET - JAN/{0} (8110)\nCORRELAÇÃO - PRECIP ACUM'.format(tri.upper())
figname = 'rsm.correl.{0}.png'.format(tri)
levs = (-1.0, -0.9, -0.7, -0.5, -0.3,
         0.3,  0.5,  0.7,  0.9,  1.0) #10
my_colors = ('#2372c9', '#3498ed', '#4ba7ef', '#76bbf3', '#93d3f6',
             '#b0f0f7', '#ffffff', '#fbe78a', '#ff9d37', '#ff5f26',
             '#ff2e1b', '#ff0219', '#ae000c') #13
pm.plotmap(correl, lats_hind, lons_hind, latsouthpoint=-38.27, latnorthpoint=13.63,
    lonwestpoint=-84.3, loneastpoint=-33., fig_name=figname, barloc='right',
    barcolor=my_colors, barlevs=levs, fig_title=figtitle, barinf='neither', ocean_mask=1)

###########  VIÉS  ###########
print(hind.shape)
print(obs.shape)
コード例 #16
0
ファイル: readmemb.py プロジェクト: marcelorodriguesss/FCST
def ProbMemb(fcst_month, fcst_year, target_year, target_months,
             hind_period, nyears, shapef, nmemb=20):

    """
    Esta função calcula a previsão (sinal) para todos
    os membros.

    :param fcst_month: mês previsão
    :type fcst_month: str

    :param fcst_year: ano do mês previsão
    :type fcst_year: str

    :param target_year: ano alvo da previsão
    :type target_year: str

    :param target_months: trimestre alvo da previsão
    :type target_months: str

    :param hind_period: período do hindcast
    :type hind_period: str

    :param nyears: número de anos do hindcast
    :type nyears: int

    :param shapef: arquivo de txt com pontos da região
    :type shapef: arquivo de txt

    :param nmemb: número de membros da preevisão/hinscast
    :type nmemb: int

    """


    #### OBSERVADO ####

    print "\n +++ LENDO A CLIMATOLOGIA OBSERVADA +++\n"

    url = 'http://opendap2.funceme.br:8001/data/dados-obs/cmap/2.5dg/' \
           'cmap.precip.season.accum.standard.2.5dg.{0}.{1}.nc' \
           .format("1981-2010", target_months)

    #~ print url

    obs_data = Dataset(url, 'r')

    obs_aux = obs_data.variables['precip'][:]

    obs_lons_360 = obs_data.variables['lon'][:]

    obs_lats = obs_data.variables['lat'][:]

    obs_data.close()

    obs_aux, obs_lons = shiftgrid(180., obs_aux, obs_lons_360, start=False)

    print " +++ INTERPOLANDO CLIMATOLOGIA OBSERVADA +++ \n"

    # Interpolação para 1 grau

    # Nova grade de 1 grau
    newlats = np.linspace(-90, 90, 181)

    newlons = np.linspace(-180, 179, 360)

    obs = np.zeros((int(obs_aux.shape[0]), int(len(newlats)), int(len(newlons))))

    x, y = np.meshgrid(newlons, newlats)

    for i in range(0, int(obs_aux.shape[0])):

        obs[i, :, :] = interp(obs_aux[i, :, :], obs_lons, obs_lats, x, y, order=1)

    #### PREVISÃO ####

    print " +++ LENDO OS MEMBROS PREVISÃO +++ \n"

    #~ Monta a url do ano da previsão com todos os membros
    url = 'http://opendap2.funceme.br:8001/data/dados-pos-processados-echam46' \
          '/forecasts/{0}/{2}/{1}/PCP/TRI/pcp-seasonacc-echam46-hind{0}-en%2.2d-{1}{2}_{3}{4}.ctl' \
          .format(hind_period, fcst_month, fcst_year, target_year, target_months)

    files = [url % d for d in range(51, 71)]

    # Inicializa array que irá receber os membros do ano da previsão
    fcst_t42 = np.zeros((20, 64, 128)) * 0

    for i, nc in enumerate(files):

        #~ print "", nc

        fcst_data = Dataset(nc, 'r')

        fcst_aux = fcst_data.variables['pcp'][:]

        fcst_lons_360 = fcst_data.variables['longitude'][:]

        fcst_lats = fcst_data.variables['latitude'][:]

        fcst_data.close()

        fcst_aux, fcst_lons = shiftgrid(180., fcst_aux, fcst_lons_360, start=False)

        fcst_t42[i, :, :] = fcst_aux[0, :, :]

    print " +++ INTERPOLANDO OS MEMBROS PREVISÃO +++ \n"

    # Interpolação para 1 grau

    # Nova grade de 1 grau

    fcst = np.zeros((20, int(len(newlats)), int(len(newlons)))) * 0

    for i in range(20):

        fcst[i, :, :] = interp(fcst_t42[i, :, :], fcst_lons, fcst_lats, x, y, order=1)

    #### HINDCAST ####

    print " +++ LENDO OS MEMBROS DE CADA ANO DO HINDCAST +++\n"

    print " ==> AGUARDE...\n"

    # Inicializa array que irá receber todos os anos e todos os membros

    hind_t42 = np.zeros((30, 20, 64, 128)) * 0

    for i, hind_year in enumerate(range(1981, 2011)):

        #~ print " ANO:", hind_year

        # Monta a url de cada ano com todos os membros
        url = 'http://opendap2.funceme.br:8001/data/dados-pos-processados-echam46' \
              '/hindcasts/{0}/{1}/PCP/TRI/pcp-seasonacc-echam46-hind{0}-en%2.2d-{1}{3}_{3}{2}.ctl' \
              .format(hind_period, fcst_month, target_months, hind_year)

        files = [url % d for d in range(51, 71)]

        # Inicializa array que irá receber os membros para cada ano
        hindmemb = np.zeros((20, 64, 128)) * 0

        for j, nc in enumerate(files):

            hind_data = Dataset(nc, 'r')

            hind_aux = hind_data.variables['pcp'][:]

            hind_lons_360 = hind_data.variables['longitude'][:]

            hind_lats = hind_data.variables['latitude'][:]

            hind_data.close()

            hind_aux, hind_lons = shiftgrid(180., hind_aux, hind_lons_360, start=False)

            hindmemb[j, :, :] = hind_aux[0, :, :]

        hind_t42[i, :, :, :] = hindmemb[:, :, :]

    print " +++ INTERPOLANDO OS ANOS DE CADA MEMBRO DO HINDCAST. +++ \n"

    print " ==> AGUARDE... \n"

    # Interpolação para 1 grau

    hind = np.zeros((30 , 20, int(len(newlats)), int(len(newlons)))) * 0

    for i in range(20):

        #~ print " MEMBRO:", i + 51

        for j in range(30):

            hind[j, i, :, :] = interp(hind_t42[j, i, :, :], hind_lons, hind_lats, x, y, order=1)

    print " +++ APLICANDO MÁSCARA DA REGIÃO +++ \n"

    # Retorna matriz com os pontos sobre o Ceará
    pointsgrid, lonlatgrid, mymatriz = dg.pointinside(newlats, newlons, shapefile=shapef)

    ce_fcst = np.ma.array(fcst, mask=np.tile(mymatriz, (fcst.shape[0], 1)))

    ce_hind = np.ma.array(hind, mask=np.tile(mymatriz, (hind.shape[0], hind.shape[1], 1)))

    ce_obs = np.ma.array(obs, mask=np.tile(mymatriz, (obs.shape[0], 1)))

    print " +++ MÉDIA DOS PONTOS SOBRE A REGIÃO PARA TODOS OS MEMBROS +++ \n"

    ave_ce_fcst = np.zeros((int(nmemb), 1)) * 0

    ave_ce_hind = np.zeros((int(nyears), int(nmemb), 1)) * 0

    ave_ce_obs = np.zeros((int(nyears), 1)) * 0

    for i in range(int(nmemb)):

        ave_ce_fcst[i, 0] = ce_fcst[i, :, :].mean()

        for j in range(int(nyears)):

            ave_ce_hind[j, i, 0] = ce_hind[j, i, :, :].mean()

    for i in range(int(nyears)):

            ave_ce_obs[i, 0] = ce_obs[i, :, :].mean()

    sig_membs_ce = np.zeros((int(nmemb))) * 0

    print " +++ CALCULANDO SINAL DA PREVISÃO PARA TODOS OS MEMBROS +++\n"

    for i in range(nmemb):
        below_ce, normal_ce, above_ce, sig_membs_ce[i], f_std_ce, \
        o_pad_ce, fcst_sig_anom = cs.compute_probability(ave_ce_fcst[i, 0],
        ave_ce_hind[:, i, 0], ave_ce_obs[:, 0], nyears)

    return sig_membs_ce
コード例 #17
0
ファイル: map_anom.py プロジェクト: marcelorodriguesss/FCST
#     pm.plotmap(anom_diff_p, nla, nlo,
#                latsouthpoint=y1, latnorthpoint=y2, lonwestpoint=x1,
#                loneastpoint=x2, fig_name=figname_anom, barloc='right',
#                barcolor=my_colors, barlevs=levs, fig_title=figtitle,
#                barinf='both', ocean_mask=1)


# diff das anomalias: controle menos experimento
for i, y in enumerate(xrange(2011, 2017)):

    directory = 'figs_expsolar/diff_anom'

    if not os.path.exists(directory):
        os.makedirs(directory)

    anom, anom_pad = cs.compute_anomaly(pcp[30 + i, :, :], pcpe[0:30, :, :])

    anom_exp, anom_pad_exp = cs.compute_anomaly(pcpe[30 + i, :, :],
                                                pcpe[0:30, :, :])

    # diff das anomalias

    anom_diff = anom_exp - anom

    figtitle = u'Anom Diff (mm) (EXP - CONTROl)'

    figname_anom = '{0}/diff_anom_{1}.png'.format(directory, y)

    levs = (-300., -100., -50., -30., -15., -5.,
            5., 15., 30., 50., 100., 300.)  # 12
コード例 #18
0
ファイル: run.1dg.jr.py プロジェクト: marcelorodriguesss/FCST
    y1, y2, x1, x2 = -60., 15., -90., -30.  # América do sul

    ##########  Apenas um plot  ##########
    lev = [0., 50., 100., 200., 300., 500., 700., 900., 1000.]
    my_colors = ('#ffffff', '#E5E5E5', '#CBCBCB', '#B2B2B2',
                 '#989898', '#7F7F7F', '#666666', '#4E4E4E') #8
    figtitle = u'ECHAM4.6 - Precip Acum (mm)'
    figname = "{5}/bra_precip_persistida_{0}_{1}-{2}_{3}_{4}_echam46_1dg_null_precip_median.png" \
              .format(hind_period_name, target_year, target_months, fcst_year, n_fcst_month, outdir)
    pm.plotmap(fcst[0, :, :], newlats-1./2., newlons-1./2., latsouthpoint=-88., latnorthpoint=88.,
               lonwestpoint=-178., loneastpoint=178., fig_name=figname, fig_title=figtitle,
               barcolor=my_colors, ocean_mask=0, barlevs=lev, barinf='max',
               barloc='bottom', meridians=np.arange(-160., 161., 30.), parallels=np.arange(-90., 91., 20.))

    ##########  Anomalia corrigida metódo do Caio (regressão linear)  ##########
    below, normal, above, f_signal, f_std, o_pad, fcst_sig_anom = cs.compute_probability(fcst, hind, obs, n_years)
    hind_corrigido = cs.compute_setrighthind(hind, obs, n_years)
    anomaly_corrigida, anomaly_pad = cs.compute_anomaly(fcst_sig_anom, hind_corrigido)
    #~ figtitle = u'ECHAM4.6 x CMAP - OCT/{4} - {1}/{4}\nAnomaly (mm) - Precip Accum ({2})'\
    figtitle = u'ECHAM4.6 x CMAP - {0}/{3} - {1}/{4}\nAnomalia (mm) - Precip Acum ({2})'\
               .format(fcst_month_name, target_months, hind_period_name, fcst_year, target_year)
    figname_anom = "{5}/bra_precip_persistida_{0}_{1}-{2}_{3}_{4}_echam46_1dg_null_anom_median.png" \
              .format(hind_period_name, target_year, target_months, fcst_year, n_fcst_month, outdir)
    levs = (-700., -500., -300., -100., -50., -30., 30.,   50.,  100.,  300., 500., 700.) #12
    my_colors = ('#340003', '#ae000c', '#ff2e1b', '#ff5f26', '#ff9d37', '#fbe78a',
                 '#ffffff', '#b0f0f7', '#93d3f6', '#76bbf3', '#4ba7ef', '#3498ed', '#2372c9') #13
    pm.plotmap(anomaly_corrigida[0, :, :], newlats-1./2., newlons-1./2., latsouthpoint=y1, latnorthpoint=y2,
        lonwestpoint=x1, loneastpoint=x2,  fig_name=figname_anom, barloc='right',
        barcolor=my_colors, barlevs=levs, fig_title=figtitle, barinf='both', ocean_mask=1)

    background = Image.open(figname_anom)
コード例 #19
0
            exit(1)

        try:
            # Arquivo observação
            obs_file = open_url(obs_url)
            pcp_obs = obs_file['precip']
            obs = np.asarray(pcp_obs)
        except:
            print "+++ Erro ao abrir arquivo do observado +++"
            print obs_url
            exit(1)

        myfcst = fsct[0, i_lat, i_lon]
        myhind = hind[:, i_lat, i_lon]
        myobs = obs[:, i_lat, i_lon]
        below, normal, above, fsignal, fstd, opad, fs_anom = cs.compute_probability(myfcst, myhind, myobs, lenhind)
        fsignal = np.expand_dims(fsignal, axis=0)
        pm.plotnorm(fsignal, fstd, opad, fig_name=figname, fig_title='')
        shutil.copy2(figname, figrealname)

    else:

        # se a imagem ja tiver sido gerada, apenas faz copia para exibir no site
        shutil.copy2(figrealname, figname)

elif myopt == "a":
    print 't1'
    pass

else:
    print 't2'