# -*- coding: utf-8 -*- #==========================================================# #Last Updated - June 2018 #@author: z5025317 Valentin Heimhuber #code for creating climate prioritization plots for NARCLIM variables. #Inputs: Uses CSV files that contain all 12 NARCLIM model runs time series for 1 grid cell created with: P1_NARCliM_NC_to_CSV_CCRC_SS.py #==========================================================# #Load packages #==========================================================# import numpy as np import os import pandas as pd import glob import matplotlib import matplotlib.pyplot as plt from datetime import datetime from datetime import timedelta from matplotlib.backends.backend_pdf import PdfPages from ggplot import * matplotlib.style.use('ggplot') # import own modules # Set working direcotry (where postprocessed NARClIM data is located) os.chdir('C:/Users/z5025317/OneDrive - UNSW/WRL_Postdoc_Manual_Backup/WRL_Postdoc/Projects/Paper#1/Analysis/Code') import climdata_fcts as fct import silo as sil ALPHA_figs = 0 font = {'family' : 'sans-serif', 'weight' : 'normal', 'size' : 14} matplotlib.rc('font', **font) #==========================================================# # Set working direcotry (where postprocessed NARClIM data is located) os.chdir('C:/Users/z5025317/OneDrive - UNSW/WRL_Postdoc_Manual_Backup/WRL_Postdoc/Projects/Paper#1/') #==========================================================# #==========================================================# #set input parameters Case_Study_Name = 'CASESTUDY2' Version = 'V5' #V4 is latest for all model runs #V5 is just for the Hunter catchment climatology Estuaries = ['HUNTER', 'RICHMOND', 'NADGEE', 'SHOALHAVEN', 'GEORGES','CATHIE'] Estuaries = ['HUNTER'] #,'HUNTER','RICHMOND'] #Estuaries = ['SHOALHAVEN'] for Est in Estuaries: #Estuary = 'HUNTER' # 'Belongil' Estuary = Est # 'Belongil' print Estuary #Clim_var_type = 'potevpmean' # '*' will create pdf for all variables in folder "pracc*|tasmax*" Clim_var_types = ['evspsblmean'] for climvar in Clim_var_types: Clim_var_type = climvar #==========================================================# #set input preferences #==========================================================# plot_pdf = 'no' plot_pngs = 'no' delta_csv = 'yes' Stats = 'mean' # 'maxdaily', 'mean', 'days_h_25' DoMonthly = True Perc_Vs_Abs = 'percent' #'percent' vs. 'absolute' deltas for near and far future Location = 'Catchment' #==========================================================# #==========================================================# #set directory path for output files output_directory = 'Output/' + Case_Study_Name + '_' + Version + '/' + Estuary #output_directory = 'J:/Project wrl2016032/NARCLIM_Raw_Data/Extracted' if not os.path.exists(output_directory): os.makedirs(output_directory) print('-------------------------------------------') print("output directory folder didn't exist and was generated") print('-------------------------------------------') #set directory path for individual png files png_output_directory = 'Output/' + Case_Study_Name + '_' + Version + '/' + Estuary + '/NARCLIM_Key_Figs' #output_directory = 'J:/Project wrl2016032/NARCLIM_Raw_Data/Extracted' if not os.path.exists(png_output_directory): os.makedirs(png_output_directory) print('-------------------------------------------') print("output directory folder didn't exist and was generated") print('-------------------------------------------') #==========================================================# #==========================================================# Estuary_Folder = glob.glob('./Data/NARCLIM_Site_CSVs/'+ Case_Study_Name + '/' + Estuary + '*' ) if Location == 'Catchment': Estuary_Folder = glob.glob('./Data/NARCLIM_Site_CSVs/'+ Case_Study_Name + '/' + Estuary + '*catch' ) Clim_Var_CSVs = glob.glob(Estuary_Folder[0] + '/' + Clim_var_type + '*') Coordinates_foldername = os.path.basename(os.path.normpath(Estuary_Folder[0])) Coordinates = Coordinates_foldername.split('_', 3)[1] + '_' +Coordinates_foldername.split('_', 3)[2] #==========================================================# #==========================================================# #read CSV files and start analysis #==========================================================# #for clim_var_csv_path in Clim_Var_CSVs: clim_var_csv_path = Clim_Var_CSVs[0] Filename = os.path.basename(os.path.normpath(clim_var_csv_path)) Clim_var_type = Filename.split('_', 1)[0] print(clim_var_csv_path) Full_df = pd.read_csv(clim_var_csv_path, index_col=0, parse_dates = True) #pandas datestamp index to period (we don't need the 12 pm info in the index (daily periods are enough)) Full_df.index = Full_df.index.to_period('D') Full_df = Full_df.drop(columns=['period']) Ncols_df = len(Full_df) #check data types of columns #Full_df.dtypes #==========================================================# #==========================================================# #substract a constant from all values to convert from kelvin to celcius (temp) if Clim_var_type in ['tasmean','tasmax','sstmean']: Full_df = Full_df.iloc[:,0:(Ncols_df-1)]-273.15 if Clim_var_type == 'evspsblmean' or Clim_var_type == 'potevpmean': Full_df = Full_df.iloc[:,0:(Ncols_df-1)]*60*60*24 if Clim_var_type in ['pr30maxtstep','pr10maxtstep','pr20maxtstep']: Full_df = Full_df.iloc[:,0:(Ncols_df-1)]*60*30 #int(Clim_var_type[2:4]) if Clim_var_type in ['pr1Hmaxtstep']: Full_df = Full_df.iloc[:,0:(Ncols_df-1)]*60*60 if Clim_var_type in ['rsdsmean','rldsmean']: Full_df = Full_df.iloc[:,0:(Ncols_df-1)]*60*60*24/1000000 #convert to unit used in SILO Fdf_1900_2080 = Full_df #==========================================================# #==========================================================# #Aggregate daily df to annual time series if Clim_var_type in ['pracc' ,'evspsblmean' ,'potevpmean' ,'pr1Hmaxtstep' , 'wss1Hmaxtstep', 'rsdsmean', 'rldsmean']: if(Stats == 'maxdaily'): Fdf_1900_2080_annual = Fdf_1900_2080.resample('A').max() Fdf_1900_2080_annual = Fdf_1900_2080_annual.replace(0, np.nan) Fdf_Seas_means = Fdf_1900_2080.resample('Q-NOV').max() #seasonal means Fdf_Seas_means = Fdf_Seas_means.replace(0, np.nan) Fdf_Monthly_means = Fdf_1900_2080.resample('M').max() #seasonal means Fdf_Monthly_means = Fdf_Monthly_means.replace(0, np.nan) elif(Stats[:4] =='days'): Threshold = int(Stats[-2:]) #agg = ('abobe_27_count', lambda x: x.gt(27).sum()), ('average', 'mean') agg = ('>'+ str(Threshold) + '_count', lambda x: x.gt(Threshold).sum()), Fdf_1900_2080_annual = Fdf_1900_2080.resample('A').agg(agg) #Fdf_1900_2080_annual = Fdf_1900_2080_annual.replace(0, np.nan) Fdf_Seas_means = Fdf_1900_2080.resample('Q-NOV').agg(agg) #seasonal means #Fdf_Seas_means = Fdf_Seas_means.replace(0, np.nan) Fdf_Monthly_means = Fdf_1900_2080.resample('M').agg(agg) else: Fdf_1900_2080_annual = Fdf_1900_2080.resample('A').sum() Fdf_1900_2080_annual = Fdf_1900_2080_annual.replace(0, np.nan) Fdf_Seas_means = Fdf_1900_2080.resample('Q-NOV').sum() #seasonal means Fdf_Seas_means = Fdf_Seas_means.replace(0, np.nan) Fdf_Monthly_means = Fdf_1900_2080.resample('M').sum() #Monthlyonal means Fdf_Monthly_means = Fdf_Monthly_means.replace(0, np.nan) else: if(Stats == 'maxdaily'): Fdf_1900_2080_annual = Fdf_1900_2080.resample('A').max() Fdf_1900_2080_annual = Fdf_1900_2080_annual.replace(0, np.nan) Fdf_Seas_means = Fdf_1900_2080.resample('Q-NOV').max() #seasonal means Fdf_Seas_means = Fdf_Seas_means.replace(0, np.nan) Fdf_Monthly_means = Fdf_1900_2080.resample('M').max() #Monthlyonal means Fdf_Monthly_means = Fdf_Monthly_means.replace(0, np.nan) elif(Stats == 'maxmonthly'): Fdf_1900_2080_annual = Fdf_1900_2080.resample('M').max().resample('A').mean() Fdf_1900_2080_annual = Fdf_1900_2080_annual.replace(0, np.nan) Fdf_Seas_means = Fdf_1900_2080.resample('M').max().resample('Q-NOV').mean() #seasonal means Fdf_Seas_means = Fdf_Seas_means.replace(0, np.nan) Fdf_Monthly_means = Fdf_1900_2080.resample('M').max().resample('Q-NOV').mean() #Monthlyonal means Fdf_Monthly_means = Fdf_Monthly_means.replace(0, np.nan) elif(Stats[:4] =='days'): Threshold = int(Stats[-2:]) #agg = ('abobe_27_count', lambda x: x.gt(27).sum()), ('average', 'mean') agg = ('>'+ str(Threshold) + '_count', lambda x: x.gt(Threshold).sum()), Fdf_1900_2080_annual = Fdf_1900_2080.resample('A').agg(agg) #Fdf_1900_2080_annual = Fdf_1900_2080_annual.replace(0, np.nan) Fdf_Seas_means = Fdf_1900_2080.resample('Q-NOV').agg(agg) #seasonal means #Fdf_Seas_means = Fdf_Seas_means.replace(0, np.nan) Fdf_Monthly_means = Fdf_1900_2080.resample('M').agg(agg) else: Fdf_1900_2080_annual = Fdf_1900_2080.resample('A').mean() Fdf_Seas_means = Fdf_1900_2080.resample('Q-NOV').mean() #seasonal means Fdf_Monthly_means = Fdf_1900_2080.resample('M').mean() #seasonal means Fdf_1900_2080_means = Fdf_1900_2080.mean() #==========================================================# #==========================================================# #Select the 3 most representative models (min med and max difference betwen far future and present) dfall, dfmin, dfmax, dfmed, Min_dif_mod_name, Med_dif_mod_name, Max_dif_mod_name = fct.select_min_med_max_dif_model(Fdf_1900_2080) #==========================================================# #==========================================================# #create a dataframe that has 1 column for each of the three representative models dfa = Fdf_1900_2080_annual.iloc[:,[0]] dfa1 = Fdf_1900_2080_annual.iloc[:,[0,3,6]].loc[(Fdf_1900_2080_annual.index >= '1990') & (Fdf_1900_2080_annual.index <= '2009')] dfa1.columns = [Min_dif_mod_name[:-5], Med_dif_mod_name[:-5], Max_dif_mod_name[:-5]] dfa2 = Fdf_1900_2080_annual.iloc[:,[1,4,7]].loc[(Fdf_1900_2080_annual.index >= '2020') & (Fdf_1900_2080_annual.index <= '2039')] dfa2.columns = [Min_dif_mod_name[:-5], Med_dif_mod_name[:-5], Max_dif_mod_name[:-5]] dfa3 = Fdf_1900_2080_annual.iloc[:,[2,5,8]].loc[(Fdf_1900_2080_annual.index >= '2060') & (Fdf_1900_2080_annual.index <= '2079')] dfa3.columns = [Min_dif_mod_name[:-5], Med_dif_mod_name[:-5], Max_dif_mod_name[:-5]] dfall_annual = dfa1.append(dfa2).append(dfa3) #==========================================================# #==========================================================# #Create Deltas of average change for annual and seasonal basis #==========================================================# delta_all_df = fct.calculate_deltas_NF_FF2(Fdf_1900_2080_annual, Fdf_Seas_means, Stats, Perc_Vs_Abs) if DoMonthly ==True: delta_all_df_monthly = fct.calculate_deltas_monthly(Fdf_Monthly_means, Stats, Perc_Vs_Abs) delta_all_df_monthly = pd.concat([delta_all_df_monthly.filter(regex= 'near'),delta_all_df_monthly.filter(regex= 'far')], axis=1)[-3:] #==========================================================# if delta_csv == 'yes': out_file_name = Estuary + '_' + Clim_var_type + '_' + Stats + '_NARCliM_ensemble_changes' + Perc_Vs_Abs + '_' + Location + '_' + Coordinates + '.csv' out_path = output_directory + '/' + out_file_name delta_all_df.to_csv(out_path) if delta_csv == 'yes' and DoMonthly ==True: out_file_name = Estuary + '_' + Clim_var_type + '_' + Stats + '_NARCliM_ensemble_changes_monthly' + Perc_Vs_Abs + '_' + Location + '_' + Coordinates + '.csv' out_path = output_directory + '/NARCLIM_Changes_Hunter/' + out_file_name delta_all_df_monthly.to_csv(out_path) #==========================================================# #==========================================================# #create a dataframe that has a single column for present day, near and far future for the (3 selected models) Full_current_df = Fdf_1900_2080.iloc[:,range(0,3)] Full_current_df = Full_current_df.stack() #nearfuture Full_nearfuture_df = Fdf_1900_2080.iloc[:,range(3,6)] Full_nearfuture_df = Full_nearfuture_df.stack() #farfuture Full_farfuture_df = Fdf_1900_2080.iloc[:,range(6,len(Fdf_1900_2080.columns))] Full_farfuture_df = Full_farfuture_df.stack() Summarized_df = pd.concat([Full_current_df, Full_nearfuture_df], axis=1, ignore_index=True) Summarized_df = pd.concat([Summarized_df, Full_farfuture_df], axis=1, ignore_index=True) Summarized_df.columns = ['present', 'near', 'far'] #==========================================================# #==========================================================# #generate colour schemes for plotting #==========================================================# plotcolours36 = ['darkolivegreen','turquoise', 'lightgreen', 'darkgreen', 'lightpink','slateblue', 'slategray', 'orange', 'tomato', 'peru', 'navy', 'teal', 'darkolivegreen','turquoise', 'lightgreen', 'darkgreen', 'lightpink','slateblue', 'slategray', 'orange', 'tomato', 'peru', 'navy', 'teal', 'darkolivegreen','turquoise', 'lightgreen', 'darkgreen', 'lightpink','slateblue', 'slategray', 'orange', 'tomato', 'peru', 'navy', 'teal'] plotcolours36b = ['tomato', 'royalblue', 'mediumpurple' , 'tomato', 'royalblue', 'mediumpurple' , 'tomato', 'royalblue', 'mediumpurple' , 'tomato', 'royalblue', 'mediumpurple' , 'tomato', 'royalblue', 'mediumpurple' , 'tomato', 'royalblue', 'mediumpurple' , 'tomato', 'royalblue', 'mediumpurple' , 'tomato', 'royalblue', 'mediumpurple' , 'tomato', 'royalblue', 'mediumpurple' , 'tomato', 'royalblue', 'mediumpurple' , 'tomato', 'royalblue', 'mediumpurple' , 'tomato', 'royalblue', 'mediumpurple' ] plotcolours12 = ['darkolivegreen','turquoise', 'lightgreen', 'darkgreen', 'lightpink','slateblue', 'slategray', 'orange', 'tomato', 'peru', 'navy', 'teal'] plotcolours15 = ['darkolivegreen','turquoise', 'lightgreen', 'darkgreen', 'lightpink','slateblue', 'slategray', 'orange', 'tomato', 'peru', 'navy', 'teal', 'lightgreen','lightpink','slateblue'] color_dict = {'CCCMA3.1_R1': 'darkolivegreen', 'CCCMA3.1_R2': 'turquoise', 'CCCMA3.1_R3': 'lightgreen', 'CSIRO-MK3.0_R2': 'darkgreen', 'CSIRO-MK3.0_R1':'lightpink', 'CSIRO-MK3.0_R3':'slateblue','ECHAM5_R1':'slategray', 'ECHAM5_R2': 'orange', 'ECHAM5_R3': 'tomato', 'MIROC3.2_R1': 'peru', 'MIROC3.2_R2': 'navy' ,'MIROC3.2_R3': 'teal', '10th':'lightgreen','median':'lightpink','90th':'slateblue'} #==========================================================# #==========================================================# #output crucial summary plots into individual png files #==========================================================# if plot_pngs == 'yes': #=========# #Barplot of near and far future deltas #=========# #out name png_out_file_name = Clim_var_type + '_' + Stats + '_Deltas_Barplot_' + Version + '.png' png_out_path = png_output_directory + '/' + png_out_file_name #prepare data frame for plot neardeltadf=delta_all_df['near'] ymin = min(neardeltadf) + 0.1 *min(neardeltadf) ymax = max(neardeltadf) + 0.1 * max(neardeltadf) neardeltadf=delta_all_df['far'] ymin2 = min(neardeltadf) + 0.1 *min(neardeltadf) ymax2 = max(neardeltadf) + 0.1 * max(neardeltadf) ymin = min(ymin, ymin2) if (Clim_var_type == 'tasmax' or Clim_var_type == 'tasmean'): ymin = 0 ymax = max(ymax, ymax2) # fig = plt.figure(figsize=(5,6)) ax=plt.subplot(2,1,1) plt.title(Clim_var_type + ' - ' + Stats + ' - deltas - near') neardeltadf=delta_all_df['near'] neardeltadf.plot(kind='bar', color=plotcolours15, ylim=(ymin,ymax), ax=ax) plt.xticks([]) ax=plt.subplot(2,1,2) plt.title(Clim_var_type + ' - ' + Stats + ' - deltas - far') neardeltadf=delta_all_df['far'] neardeltadf.plot(kind='bar', color=plotcolours15, ylim=(ymin,ymax), ax=ax) ax.xaxis.grid(False) #ax.patch.set_alpha(ALPHA_figs) fig.patch.set_alpha(ALPHA_figs) fig.tight_layout() fig.savefig(png_out_path) plt.close() #=========# #=========# #full period density comparison #=========# #out name png_out_file_name = Clim_var_type + '_' + Stats + '_MaxDeltaMod_Histogram_' + Version + '.png' png_out_path = png_output_directory + '/' + png_out_file_name plt.title(Clim_var_type + ' - ' + Stats + ' - hist - full period - max delta model') #prepare data xmin = float(max(np.nanpercentile(Fdf_1900_2080.filter(regex= Max_dif_mod_name[:-5]),50) - 4 * np.std(Fdf_1900_2080.filter(regex= Max_dif_mod_name[:-5])))) xmax = float(max(np.nanpercentile(Fdf_1900_2080.filter(regex= Max_dif_mod_name[:-5]),50) + 4 * np.std(Fdf_1900_2080.filter(regex= Max_dif_mod_name[:-5])))) fig = plt.figure(figsize=(5,5)) ax=plt.subplot(2,1,1) Fdf_1900_2080.filter(regex= Max_dif_mod_name[:-5]).plot.kde(xlim=(xmin,xmax), ax=ax) plt.legend(loc=9, bbox_to_anchor=(0.5, -0.3)) #ax.xaxis.grid(False) ax.yaxis.grid(False) fig.patch.set_alpha(ALPHA_figs) fig.tight_layout() fig.savefig(png_out_path) plt.close() #=========# #=========# # time series plot annual ALL models #=========# png_out_file_name = Clim_var_type + '_' + Stats + '_TimeSeries_AllMods_' + Version + '3.png' png_out_path = png_output_directory + '/' + png_out_file_name plt.title(Clim_var_type + ' - ' + Stats + ' - Time series - representative models') #prepare data # Mod_order = [1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,19,20,21,16,17,18,22,23,24,31,32,33,25,26,27,28,29,30,34,35,36] # test = Fdf_1900_2080_annual # Mod_Names = test.columns # New_Mod_Name = [] # for i in range(0,len(Mod_Names)): # if(Stats[:4] =='days'): # New_Mod_Name.append(str(Mod_order[i]+10) + '_' + Mod_Names[i][0]) # else: # New_Mod_Name.append(str(Mod_order[i]+10) + '_' + Mod_Names[i]) # test.columns = New_Mod_Name # test_sorted = test.reindex_axis(sorted(test.columns), axis=1) # colnamest = test.columns # test_sorted.columns = [w[3:-5] for w in colnamest] #plot fig = plt.figure(figsize=(8,7)) ax=plt.subplot(2,1,1) #test_sorted.plot(ax=ax) #,color = plotcolours36) Fdf_1900_2080_annual_b = Fdf_1900_2080_annual New_Mod_Name = [] if(Stats[:4] =='days'): for each in Fdf_1900_2080_annual_b.columns: New_Mod_Name.append(each[0][:-5]) else: for each in Fdf_1900_2080_annual_b.columns: New_Mod_Name.append(each[:-5]) Fdf_1900_2080_annual_b.columns = New_Mod_Name Fdf_1900_2080_annual_b.plot(ax=ax, color=[color_dict[x] for x in Fdf_1900_2080_annual_b.columns]) plt.legend(loc=9, bbox_to_anchor=(0.5, -0.2)) ax.xaxis.grid(False) fig.patch.set_alpha(ALPHA_figs) fig.tight_layout() fig.savefig(png_out_path) plt.close() #=========# #==========================================================# #output some summary plot into pdf #==========================================================# if plot_pdf == 'yes': #plt.cm.Paired(np.arange(len(Fdf_1900_2080_means))) #write the key plots to a single pdf document pdf_out_file_name = Clim_var_type + '_' + Stats + '_NARCliM_summary_' + Version + '.pdf' pdf_out_path = output_directory +'/' + pdf_out_file_name #open pdf and add the plots with PdfPages(pdf_out_path) as pdf: #barplot of model means plt.title(Clim_var_type + ' - model means - full period') ymin = min(Fdf_1900_2080_means) ymax = max(Fdf_1900_2080_means) + 0.008 *min(Fdf_1900_2080_means) Fdf_1900_2080_means.plot(kind='bar', ylim=(ymin,ymax), color=plotcolours36) pdf.savefig(bbox_inches='tight', pad_inches=0.4) plt.close() # neardeltadf=delta_all_df['near'] ymin = min(neardeltadf) + 0.1 *min(neardeltadf) ymax = max(neardeltadf) + 0.1 * max(neardeltadf) neardeltadf=delta_all_df['far'] ymin2 = min(neardeltadf) + 0.1 *min(neardeltadf) ymax2 = max(neardeltadf) + 0.1 * max(neardeltadf) ymin = min(ymin, ymin2) if (Clim_var_type == 'tasmax' or Clim_var_type == 'tasmean'): ymin = 0 ymax = max(ymax, ymax2) # # delta barplot for report 1################################# ax=plt.subplot(2,1,1) plt.title(Clim_var_type + ' - model deltas - near-present') neardeltadf=delta_all_df['near'] neardeltadf.plot(kind='bar', color=plotcolours15, ylim=(ymin,ymax), ax=ax) ax.patch.set_alpha(ALPHA_figs) plt.xticks([]) #ax.xaxis.set_ticklabels([]) #pdf.savefig(bbox_inches='tight', ylim=(ymin,ymax), pad_inches=0.4) #plt.close() # ax=plt.subplot(2,1,2) plt.title(Clim_var_type + ' - model deltas - far-present') neardeltadf=delta_all_df['far'] fig = neardeltadf.plot(kind='bar', color=plotcolours15, ylim=(ymin,ymax), ax=ax) ax.xaxis.grid(False) ax.patch.set_alpha(ALPHA_figs) #fig.patch.set_alpha(ALPHA_figs) #plt.show() pdf.savefig(bbox_inches='tight', ylim=(ymin,ymax), pad_inches=0.4) plt.close() # end delta barplot for report 1################################# # #full period density comparison plt.title(Clim_var_type + ' - density comparison - full period - all models') Summarized_df.plot.kde() pdf.savefig(bbox_inches='tight', pad_inches=0.4) plt.close() #full period density comparison plt.title(Clim_var_type + ' - density comparison - full period - max delta model') xmin = float(max(np.nanpercentile(Fdf_1900_2080.filter(regex= Max_dif_mod_name[:-5]),50) - 4 * np.std(Fdf_1900_2080.filter(regex= Max_dif_mod_name[:-5])))) xmax = float(max(np.nanpercentile(Fdf_1900_2080.filter(regex= Max_dif_mod_name[:-5]),50) + 4 * np.std(Fdf_1900_2080.filter(regex= Max_dif_mod_name[:-5])))) Fdf_1900_2080.filter(regex= Max_dif_mod_name[:-5]).plot.kde(xlim=(xmin,xmax)) pdf.savefig(bbox_inches='tight', pad_inches=0.4) fig.patch.set_alpha(ALPHA_figs) plt.close() #annual box plt.title(Clim_var_type + ' - Annual means/sums for max diff model') Fdf_1900_2080_annual.boxplot(rot=90) pdf.savefig(bbox_inches='tight', pad_inches=0.4) plt.close() # #daily box plt.title(Clim_var_type + ' - Daily means/sums') Fdf_1900_2080.boxplot(rot=90) pdf.savefig(bbox_inches='tight', pad_inches=0.4) plt.close() # time series plot annual ALL models plt.title(Clim_var_type + ' - Time series - all models') Mod_order = [1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,19,20,21,16,17,18,22,23,24,31,32,33,25,26,27,28,29,30,34,35,36] test = Fdf_1900_2080_annual Mod_Names = test.columns New_Mod_Name = [] for i in range(0,len(Mod_Names)): New_Mod_Name.append(str(Mod_order[i]+10) + '_' + Mod_Names[i]) test.columns = New_Mod_Name test_sorted = test.reindex_axis(sorted(test.columns), axis=1) colnamest = test.columns test_sorted.columns = [w[3:-5] for w in colnamest] fig = test_sorted.plot(legend=False, color = plotcolours36) pdf.savefig(bbox_inches='tight', pad_inches=0.4) fig.patch.set_alpha(ALPHA_figs) plt.close() # time series plot annual ALL models plt.title(Clim_var_type + ' - Time series - representative models') dfall_annual.plot(legend=False) pdf.savefig(bbox_inches='tight', pad_inches=0.4) plt.close() # seasonal mean boxplots ymin = min(Fdf_Seas_means[Fdf_Seas_means.index.quarter==1].mean()) ymax = max(Fdf_Seas_means[Fdf_Seas_means.index.quarter==1].mean()) plt.title(Clim_var_type + ' - DJF Summer means/sums') pd.DataFrame(Fdf_Seas_means[Fdf_Seas_means.index.quarter==1].mean()).plot(kind='bar', ylim=(ymin,ymax)) pdf.savefig(bbox_inches='tight', pad_inches=0.4) plt.close() plt.title(Clim_var_type + ' - DJF Summer means/sums') Fdf_Seas_means[Fdf_Seas_means.index.quarter==1].boxplot(rot=90) pdf.savefig(bbox_inches='tight', pad_inches=0.4) plt.close() ymin = min(Fdf_Seas_means[Fdf_Seas_means.index.quarter==2].mean()) ymax = max(Fdf_Seas_means[Fdf_Seas_means.index.quarter==2].mean()) plt.title(Clim_var_type + ' - MAM Autumn means/sums') pd.DataFrame(Fdf_Seas_means[Fdf_Seas_means.index.quarter==2].mean()).plot(kind='bar', ylim=(ymin,ymax)) pdf.savefig(bbox_inches='tight', pad_inches=0.4) plt.close() plt.title(Clim_var_type + ' - MAM Autumn means/sums') Fdf_Seas_means[Fdf_Seas_means.index.quarter==2].boxplot(rot=90) pdf.savefig(bbox_inches='tight', pad_inches=0.4) plt.close() ymin = min(Fdf_Seas_means[Fdf_Seas_means.index.quarter==3].mean()) ymax = max(Fdf_Seas_means[Fdf_Seas_means.index.quarter==3].mean()) plt.title(Clim_var_type + ' - JJA Winter means/sums') pd.DataFrame(Fdf_Seas_means[Fdf_Seas_means.index.quarter==3].mean()).plot(kind='bar', ylim=(ymin,ymax)) pdf.savefig(bbox_inches='tight', pad_inches=0.4) plt.close() plt.title(Clim_var_type + ' - JJA Winter means/sums') Fdf_Seas_means[Fdf_Seas_means.index.quarter==3].boxplot(rot=90) pdf.savefig(bbox_inches='tight', pad_inches=0.4) plt.close() ymin = min(Fdf_Seas_means[Fdf_Seas_means.index.quarter==4].mean()) ymax = max(Fdf_Seas_means[Fdf_Seas_means.index.quarter==4].mean()) plt.title(Clim_var_type + ' - SON Spring means/sums') pd.DataFrame(Fdf_Seas_means[Fdf_Seas_means.index.quarter==4].mean()).plot(kind='bar', ylim=(ymin,ymax)) pdf.savefig(bbox_inches='tight', pad_inches=0.4) plt.close() plt.title(Clim_var_type + ' - SON Spring means/sums') Fdf_Seas_means[Fdf_Seas_means.index.quarter==4].boxplot(rot=90) pdf.savefig(bbox_inches='tight', pad_inches=0.4) plt.close()