def mapTerrain(nest,includePMSL=False,includeTemp=False): """Creates a map of the domain, showing filled contours of the terrain """ nc = openWRF(nest) met = openWPS(nest) nc1 = openWRF(nest+1) _Nx,_Ny,_Nz,longitude,latitude,_dx,_dy,_x,_y = getDimensions(nc) m = _getMapForNC(nc,False,_getDL(nest),100) x, y = m(longitude,latitude) _makeDots(m) if (includeTemp and met is not None): ST = met.variables['TT'][0][0,:,:] cs = plt.contour(x,y, ST-T_zero,arange(-48,50,2.),colors='blue',linestyles='solid') plt.clabel(cs, inline=1, fmt='%1.0f', fontsize=12) if (includePMSL and met is not None): levels = arange(960.,1040.,1.) PMSL = met.variables['PMSL'][0] cs = plt.contour(x,y, PMSL/100.,levels,colors='black',label='Pressure') plt.clabel(cs, inline=1, fmt='%1.0f', fontsize=11) heightground = (nc.variables['PH'][0][0,:,:] + nc.variables['PHB'][0][0,:,:])/g plt.contourf(x, y, heightground, levels=arange(0,max_h,100),cmap=cmap_grey,extend='max') plt.colorbar() if (nc1 is not None): _plotBorder(nc1,m,'black') plt.show() plt.close()
def mapTerrain(nest, includePMSL=False, includeTemp=False): """Creates a map of the domain, showing filled contours of the terrain """ nc = openWRF(nest) met = openWPS(nest) nc1 = openWRF(nest + 1) _Nx, _Ny, _Nz, longitude, latitude, _dx, _dy, _x, _y = getDimensions(nc) m = _getMapForNC(nc, False, _getDL(nest), 100) x, y = m(longitude, latitude) _makeDots(m) if includeTemp and met is not None: ST = met.variables["TT"][0][0, :, :] cs = plt.contour(x, y, ST - T_zero, arange(-48, 50, 2.0), colors="blue", linestyles="solid") plt.clabel(cs, inline=1, fmt="%1.0f", fontsize=12) if includePMSL and met is not None: levels = arange(960.0, 1040.0, 1.0) PMSL = met.variables["PMSL"][0] cs = plt.contour(x, y, PMSL / 100.0, levels, colors="black", label="Pressure") plt.clabel(cs, inline=1, fmt="%1.0f", fontsize=11) heightground = (nc.variables["PH"][0][0, :, :] + nc.variables["PHB"][0][0, :, :]) / g plt.contourf(x, y, heightground, levels=arange(0, max_h, 100), cmap=cmap_grey, extend="max") plt.colorbar() if nc1 is not None: _plotBorder(nc1, m, "black") plt.show() plt.close()
def mapCloud(nest, time): """Creates a map of the domain, showing filled contours of the cloud water """ nc = openWRF(nest) _Nx, _Ny, _Nz, longitude, latitude, _dx, _dy, _x, _y = getDimensions(nc) m = _getMapForNC(nc, False, _getDL(nest), 100) x, y = m(longitude, latitude) qcloud = 1000.0 * np.sum(nc.variables["QCLOUD"][time, :, :, :], axis=0) plt.contourf(x, y, qcloud, cmap=cmap_red) plt.colorbar() plt.show() plt.close()
def mapCloud(nest, time): """Creates a map of the domain, showing filled contours of the cloud water """ nc = openWRF(nest) _Nx, _Ny, _Nz, longitude, latitude, _dx, _dy, _x, _y = getDimensions(nc) m = _getMapForNC(nc, False, _getDL(nest), 100) x, y = m(longitude, latitude) qcloud = 1000.0 * np.sum(nc.variables['QCLOUD'][time, :, :, :], axis=0) plt.contourf(x, y, qcloud, cmap=cmap_red) plt.colorbar() plt.show() plt.close()
def mapTerrain(nest, includePMSL=False, includeTemp=False): """Creates a map of the domain, showing filled contours of the terrain """ nc = openWRF(nest) met = openWPS(nest) nc1 = openWRF(nest + 1) _Nx, _Ny, _Nz, longitude, latitude, _dx, _dy, _x, _y = getDimensions(nc) m = _getMapForNC(nc, False, _getDL(nest), 100) x, y = m(longitude, latitude) _makeDots(m) if (includeTemp and met is not None): ST = met.variables['TT'][0][0, :, :] cs = plt.contour(x, y, ST - T_zero, arange(-48, 50, 2.), colors='blue', linestyles='solid') plt.clabel(cs, inline=1, fmt='%1.0f', fontsize=12) if (includePMSL and met is not None): levels = arange(960., 1040., 1.) PMSL = met.variables['PMSL'][0] cs = plt.contour(x, y, PMSL / 100., levels, colors='black', label='Pressure') plt.clabel(cs, inline=1, fmt='%1.0f', fontsize=11) heightground = (nc.variables['PH'][0][0, :, :] + nc.variables['PHB'][0][0, :, :]) / g plt.contourf(x, y, heightground, levels=arange(0, max_h, 100), cmap=cmap_grey, extend='max') plt.colorbar() if (nc1 is not None): _plotBorder(nc1, m, 'black') plt.show() plt.close()
def xzCloudPlot(nest,time,plotTemp=True,plotRH=False): nc = openWRF(nest) Nx,Ny,Nz,longitude,_lats,_dx,_dy,x_nr,y_nr = getDimensions(nc) heightground_x,heighthalf_xz = _getHeight(nc, time, Nx, -1, Nz, -1, y_nr) print 'Model height: ' + str(heightground_x[x_nr]) theta = nc.variables['T'][time,:,y_nr,:] + T_base P = nc.variables['P'][time,:,y_nr,:] + nc.variables['PB'][time,:,y_nr,:] T = theta*(P/P_bot)**kappa # Temperatur i halvflatene (Kelvin) rho = P/(R*T) #[kg/m3] qcloud_xz = 1000.0*nc.variables['QCLOUD'][time,:,y_nr,:]*rho # regner om til g/m3 qrain_xz = 1000.0*nc.variables['QRAIN'][time,:,y_nr,:]*rho qsnow_xz = 1000.0*nc.variables['QSNOW'][time,:,y_nr,:]*rho plt.figure() plt.set_cmap(cmap_red) plt.axis([0,Nx-1,0.0,z_max]) print u'Cloud water red, snow blue, rain green ($g/m^3$)' grid = np.reshape(np.tile(arange(Nx),Nz),(Nz,-1)) plt.contourf(grid, heighthalf_xz, qcloud_xz, alpha=0.9,levels=xz_cloudwater_levels, cmap=cmap_red)# plt.colorbar() plt.contourf(grid, heighthalf_xz, qrain_xz, alpha=0.6,levels=xz_rain_levels, cmap=cmap_green)# plt.colorbar() plt.contourf(grid, heighthalf_xz, qsnow_xz, alpha=0.6,levels=xz_snow_levels,cmap=cmap_blue)# plt.colorbar() if plotTemp: temp_int = arange(-80.0,50.0,2.0) cs = plt.contour(grid, heighthalf_xz, T-T_zero, temp_int,colors='black',linestyles='solid')#linewidths=4 plt.clabel(cs, inline=1, fmt='%1.0f', fontsize=12,colors='black') if plotRH: rh = _getRH(nc,time,-1,y_nr,T,P) rh_int = arange(90.,111.,5.) cs = plt.contour(grid, heighthalf_xz,rh , rh_int, colors='grey') plt.clabel(cs, inline=1, fmt='%1.0f', fontsize=12, colors='grey') plt.plot(arange(Nx),heightground_x,color='black') plt.fill_between(arange(Nx),heightground_x,0,facecolor='lightgrey') plt.xticks(np.arange(0,Nx,8),np.round(longitude[Ny/2,::8], 1), fontsize='small') plt.yticks(np.arange(0,z_max,dz), fontsize='small') plt.xlabel('Lengdegrad') plt.ylabel(u'Høyde [m]') plt.show() plt.close()
from sklearn.preprocessing import MinMaxScaler sc = MinMaxScaler() X = sc.fit_transform(X) #training the Som from minisom import MiniSom som = MiniSom(x=10, y=10, input_len=15, sigma=1.0, learning_rate=0.5) som.random_weights_init(X) som.train_random(data=X, num_iteration=100) # Visualizing the results from pyplot import bone, pcolor, colorbar, plot, show bone() pcolor(som.distance_map().T) colorbar() marker = ['o', 's'] color = ['r', 'g'] for i, x in enumerate(X): w = som.winner(X) plot(w[0] + 0.5, w[1] + 0.5, markers[y[i]], markeredgecolor=colors[y[i]], markerfacecolor=None, markersize=10, markeredgewidth=2) show() #Finding the fraud
def tzCloudPlot(nest, plotMetar=False, offset=0): nc = openWRF(nest) Nx, Ny, Nz, _longs, _lats, _dx, _dy, x_nr, y_nr = getDimensions(nc) heightground_t, heighthalf_tz = _getHeight(nc, Nx, Ny, Nz, x_nr, y_nr) T_tz = np.zeros((Nz, Nt)) qcloud_tz = np.zeros((Nz, Nt)) qice_tz = np.zeros((Nz, Nt)) qsnow_tz = np.zeros((Nz, Nt)) qrain_tz = np.zeros((Nz, Nt)) for t in arange(Nt): theta = nc.variables['T'][t, :, y_nr, x_nr] + T_base P = nc.variables['P'][t, :, y_nr, x_nr] + nc.variables['PB'][t, :, y_nr, x_nr] T_tz[:, t] = theta * (P / P_bot)**kappa # Temperatur i halvflatene (Kelvin) rho = P[:] / (R * T_tz[:, t]) # regner om til g/m3 qcloud_tz[:, t] = 1000.0 * nc.variables['QCLOUD'][t, :, y_nr, x_nr] * rho qice_tz[:, t] = 1000.0 * nc.variables['QICE'][t, :, y_nr, x_nr] * rho qsnow_tz[:, t] = 1000.0 * nc.variables['QSNOW'][t, :, y_nr, x_nr] * rho qrain_tz[:, t] = 1000.0 * nc.variables['QRAIN'][t, :, y_nr, x_nr] * rho for s in [u'Snø', 'Regn']: plt.figure() plt.axis([-offset, Nt - 1, 0.0, z_max]) grid = np.reshape(np.tile(arange(Nt), Nz), (Nz, -1)) if (s == u"Snø"): var = qsnow_tz cm = cmap_blue levs = tz_snow_levels else: var = qrain_tz cm = cmap_green levs = tz_rain_levels plt.contourf(grid, heighthalf_tz, qcloud_tz, alpha=0.9, levels=tz_cloudwater_levels, cmap=cmap_red) # plt.colorbar() plt.contourf(grid, heighthalf_tz, var, alpha=0.6, levels=levs, cmap=cm) # plt.colorbar() cs = plt.contour(grid, heighthalf_tz, T_tz - T_zero, temp_int, colors='black', linestyles='solid') plt.clabel(cs, inline=1, fmt='%1.0f', fontsize=12, colors='black') plt.fill_between(arange(-offset, Nt), heightground_t[0], 0, facecolor='lightgrey') if plotMetar: _metar() print s + ' ($g/m^3$)' plt.xlabel('Timer etter ' + date + 'T00:00Z') plt.ylabel(u'Høyde [m]') plt.yticks(np.arange(0, z_max, dz), fontsize='small') plt.show() plt.close() fig = plt.figure() ax1 = fig.add_subplot(111) ax1.set_xlim(0, Nt - 1) ax1.plot(np.sum(qcloud_tz, axis=0), color='black', label=u"skyvann") ax1.plot(np.sum(qsnow_tz, axis=0), color='green', label=u"snø") ax1.set_xlabel('Timer etter ' + date + 'T00:00Z') ax1.set_ylabel(u'Skyvann og snø ($g/m^2$)') ax2 = ax1.twinx() ax2.plot(np.sum(qice_tz, axis=0), color='blue', label="is") ax2.plot(np.sum(qrain_tz, axis=0), color='red', label="regn") ax2.set_ylabel('Regn og is ($g/m^2$)') ax1.set_xlim(0, Nt - 1) ax1.legend(loc='upper left') ax2.legend(loc='upper right') plt.show() plt.close()
def yzCloudPlot(nest, time, plotTemp=True, plotRH=False): nc = openWRF(nest) Nx, Ny, Nz, _longs, latitude, _dx, _dy, x_nr, y_nr = getDimensions(nc) heightground_y, heighthalf_yz = _getHeight(nc, time, -1, Ny, Nz, x_nr, -1) print 'Model height: ' + str(heightground_y[y_nr]) theta = nc.variables['T'][time, :, :, x_nr] + T_base P = nc.variables['P'][time, :, :, x_nr] + nc.variables['PB'][time, :, :, x_nr] T = theta * (P / P_bot)**kappa # Temperatur i halvflatene (Kelvin) rho = P / (R * T) #[kg/m3] qcloud_yz = 1000.0 * nc.variables['QCLOUD'][ time, :, :, x_nr] * rho # regner om til g/m3 qrain_yz = 1000.0 * nc.variables['QRAIN'][time, :, :, x_nr] * rho qsnow_yz = 1000.0 * nc.variables['QSNOW'][time, :, :, x_nr] * rho plt.figure() plt.set_cmap(cmap_red) plt.axis([0, Ny - 1, 0.0, z_max]) print u'Cloud water red, snow blue, rain green ($g/m^3$)' grid = np.reshape(np.tile(arange(Ny), Nz), (Nz, -1)) plt.contourf(grid, heighthalf_yz, qcloud_yz, alpha=0.9, levels=xz_cloudwater_levels, cmap=cmap_red) # plt.colorbar() plt.contourf(grid, heighthalf_yz, qrain_yz, alpha=0.6, levels=xz_rain_levels, cmap=cmap_green) # plt.colorbar() plt.contourf(grid, heighthalf_yz, qsnow_yz, alpha=0.6, levels=xz_snow_levels, cmap=cmap_blue) # plt.colorbar() if plotTemp: cs = plt.contour(grid, heighthalf_yz, T - T_zero, temp_int, colors='black', linestyles='solid') #linewidths=4 plt.clabel(cs, inline=1, fmt='%1.0f', fontsize=12, colors='black') if plotRH: rh = _getRH(nc, time, x_nr, -1, T, P) rh_int = arange(90., 111., 5.) cs = plt.contour(grid, heighthalf_yz, rh, rh_int, colors='grey') plt.clabel(cs, inline=1, fmt='%1.0f', fontsize=12, colors='grey') plt.plot(arange(Ny), heightground_y, color='black') plt.fill_between(arange(Ny), heightground_y, 0, facecolor='lightgrey') plt.xticks(np.arange(0, Ny, 8), np.round(latitude[::8, Nx / 2], 1), fontsize='small') plt.yticks(np.arange(0, z_max, dz), fontsize='small') plt.xlabel('Breddegrad') plt.ylabel(u'Høyde [m]') plt.show() plt.close()