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308 lines
11 KiB
Python
308 lines
11 KiB
Python
# python 3.5
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#requires LAStools to be installed (with the appropriate license). Note that LAStools requires no spaces in file names
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#should have previously run 2017088_las_manipulation to have a las that has the buildings and veg removed
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#note that the neilson volumes script must be in the same folder
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# this script will:
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#crop to a given polygon (crop away the swash zone)
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# extract values along a predefined profile,
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# do the volume analysis
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#export pngs of the surveys
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########################### IMPORTS ###########################################
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import os
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import io
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import subprocess
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import pandas as pd
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import numpy as np
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import neilson_volumes
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import matplotlib.pyplot as plt
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from matplotlib.ticker import MultipleLocator
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import datetime
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import xlsxwriter
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import math
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from cycler import cycler
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from survey_tools import call_lastools, extract_pts, update_survey_output
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def plot_profiles(profile_info, profile, output_loc, LL_limit):
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#plot the profile. expects output from CC_split_profile
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YminorLocator=MultipleLocator(0.5)
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XminorLocator=MultipleLocator(5)
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fig,ax=plt.subplots(figsize=(8, 3))
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num_plots=len(profile_info.keys())-1
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colormap = plt.cm.jet
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ax.set_prop_cycle(cycler('color', [colormap(i) for i in np.linspace(0, 0.9, num_plots)]))
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max_y=0
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for date in profile_info.keys():
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if date!='info':
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plt.plot(profile_info[date]['Chainage'], profile_info[date]['Elevation'], label=date)
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try:
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if max([i for i in profile_info[date]['Elevation'] if pd.isnull(i)==False])>max_y:
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max_y=max([i for i in profile_info[date]['Elevation'] if pd.isnull(i)==False])
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except:
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print("empty elevation section for %s" % date)
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plt.plot([LL_limit,LL_limit], [-1,max_y], 'r--', alpha=0.5, label="Landward Limit")
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plt.xlabel('Chainage (m)',weight='bold')
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plt.ylabel('Elevation (m AHD)',weight='bold')
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plt.legend(loc='upper right', bbox_to_anchor=(1.3,1))
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plt.title(profile)
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plt.rcParams['font.size']=8
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ax.set_ylim([-1,math.ceil(max_y)])
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ax.xaxis.set_minor_locator(XminorLocator)
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ax.yaxis.set_minor_locator(YminorLocator)
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ax.xaxis.grid(True, which='minor', color='k', linestyle='-', alpha=0.3)
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ax.yaxis.grid(True,which='minor',color='k', linestyle='-', alpha=0.3)
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plt.grid(which='major', color='k', linestyle='-')
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today=datetime.datetime.now().date().strftime('%Y%m%d')
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plt.savefig(os.path.join(output_loc, '%s_%s.png' % (today, profile)),bbox_inches='tight',dpi=900)
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plt.clf()
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return None
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def CC_split_profile(file2read):
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# this reads the profile files and splits it into dates
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file_master=pd.read_csv(file2read)
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beach_original=file_master['Beach'].tolist()
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profile_original=file_master['Profile'].tolist()
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date_original=file_master['Date'].tolist()
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chainage_original=file_master['Chainage'].tolist()
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elevation_original=file_master['Elevation'].tolist()
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easting_original=file_master['Easting'].tolist()
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northing_original=file_master['Northing'].tolist()
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data={}
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i=0
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#add info on the beach and profile number
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data['info']={'Profile':profile_original[0], 'Beach':beach_original[0]}
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date_now=date_original[0]
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while i<len(file_master):
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chainage_tmp=[]
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elevation_tmp=[]
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easting_tmp=[]
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northing_tmp=[]
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while i<len(file_master) and date_now==date_original[i]:
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chainage_tmp.append(chainage_original[i])
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elevation_tmp.append(elevation_original[i])
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easting_tmp.append(easting_original[i])
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northing_tmp.append(northing_original[i])
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i=i+1
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data[date_now]={'Beach': beach_original[i-1], 'Profile':profile_original[i-1],'Easting': easting_tmp, 'Northing':northing_tmp, 'Elevation':elevation_tmp, 'Chainage':chainage_tmp}
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if i<len(file_master):
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date_now=date_original[i]
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return data
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def profile_plots_volume(csv_loc, LL_xlsx, output_xlsx, graph_location):
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#get a list of all csvs which will each be analysed
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file_list=[]
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for file in os.listdir(csv_loc):
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if file.endswith(".csv"):
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file_list.append(os.path.join(csv_loc, file))
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#now read the LL file
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LL_limit_file=pd.read_excel(LL_xlsx, 'profile_locations')
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LL_info={}
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for i in range(0, len(LL_limit_file)):
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#make a dictionary that alllows you to search the LL
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prof="%s_%s" % (LL_limit_file['Profile'][i].split(" ")[0], LL_limit_file['Profile'][i].split(" ")[-1])
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LL_info[prof]=LL_limit_file['Landward Limit'][i]
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all_dates=[]
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results_volume={}
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for file in file_list:
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#read the profile data - this should have all dates
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profile_data=CC_split_profile(file)
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profile=profile_data['info']['Profile']
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#plot all of the profiles
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print(profile)
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plot_profiles(profile_data, profile, graph_location,LL_info[profile])
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results_volume[profile]={}
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#nowgo through each date and do a neilson volume calculations
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for date in profile_data.keys():
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if date!='info':
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if date not in all_dates:
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all_dates.append(date)
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chainage=profile_data[date]['Chainage']
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elevation=[0 if pd.isnull(profile_data[date]['Elevation'][i]) else profile_data[date]['Elevation'][i] for i in range(0, len(profile_data[date]['Elevation']))]
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LL_limit=LL_info[profile]
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#do a neilson calculation to get the ZSA volume
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if len(elevation)>2:
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#if there aren't enough available points don't do it
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volume=neilson_volumes.volume_available(chainage, elevation, LL_limit)
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if volume<0:
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volume=0
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print('%s %s has a negative volume available' % (profile, date))
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else:
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volume=0
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results_volume[profile][date]=volume
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#write an excel sheet which summarises the data
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workbook = xlsxwriter.Workbook(output_xlsx)
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worksheet=workbook.add_worksheet('Volumes')
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row=0
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col=0
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worksheet.write(row, col, 'Profile')
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for date in all_dates:
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col=col+1
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worksheet.write(row, col, date)
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col=0
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row=1
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for prof in results_volume.keys():
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worksheet.write(row, col, prof)
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for date in all_dates:
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col=col+1
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try:
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vol=results_volume[prof][date]
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except KeyError:
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print("error with profile %s on %s" % (prof, date))
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vol=None
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worksheet.write(row, col, vol)
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col=0
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row=row+1
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return results_volume
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def remove_temp_files(directory):
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for f in os.listdir(directory):
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os.unlink(os.path.join(directory, f))
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return None
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input_file = 'Parameter Files/las-manipulation-survey-2.xlsx'
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params_file=pd.read_excel(input_file, sheet_name="PARAMS")
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for i, row in params_file.iterrows():
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print("Starting to process %s" % row['Beach'])
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beach=row['Beach']
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survey_date = row['SURVEY DATE']
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original_las = row['INPUT LAS']
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classified_las_dir = row['LAS CLASSIFIED FOLDER']
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shp_swash_dir = row['SHP SWASH FOLDER']
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crop_heatmap_poly = row['HEATMAP CROP POLY']
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output_las_dir = row['LAS OUTPUT FOLDER']
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zone_MGA = row['ZONE MGA']
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output_poly_dir = row['SHP RASTER FOLDER']
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output_tif_dir = row['TIF OUTPUT FOLDER']
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cp_csv = row['INPUT CSV']
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profile_limit_file = row['PROFILE LIMIT FILE']
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csv_output_dir = row['CSV OUTPUT FOLDER']
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graph_loc = row['PNG OUTPUT FOLDER']
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volume_output = row['CSV VOLUMES FOLDER']
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tmp_dir = row['TMP FOLDER']
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# Get base name of input las
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las_basename = os.path.splitext(os.path.basename(original_las))[0]
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# Get name of input point cloud
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input_las = os.path.join(classified_las_dir, las_basename + '.las')
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# Get name of swash cropping polygon
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crop_swash_poly = os.path.join(shp_swash_dir, las_basename + '.shp')
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# Crop point cloud to swash boundary
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las_data = call_lastools('lasclip', input=input_las, output='-stdout',
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args=['-poly', crop_swash_poly], verbose=False)
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# crop_las(input_las5, crop_swash_poly, final_las, path_2_lastools)
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# Apply sea-side clipping polygon
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las_data = call_lastools('lasclip', input=las_data, output='-stdout',
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args=['-poly', crop_heatmap_poly], verbose=False)
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# crop_las(final_las, heatmap_crop_poly, heatmap_las, path_2_lastools)
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# Create clipping polygon for heatmap raster
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shp_name = os.path.join(output_poly_dir, las_basename + '.shp')
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call_lastools('lasboundary', input=las_data, output=shp_name, verbose=False)
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# las_boundary(heatmap_las, output_poly_name, output_poly_dir, path_2_lastools, zone_MGA)
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#make a raster
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# make_raster(heatmap_las, output_raster, path_2_lastools, keep_only_ground=True)
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tif_name = os.path.join(output_tif_dir, las_basename + '.tif')
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call_lastools('blast2dem', input=las_data, output=tif_name,
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args=['-step', 0.2], verbose=False)
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#extract the points and get volumes
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df = extract_pts(
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las_data,
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cp_csv,
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survey_date,
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beach,
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args=['-parse', 'sxyz', '-keep_class', '2'],
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verbose=False)
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update_survey_output(df, csv_output_dir)
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#colourise the point cloud
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#delete the temp files from the tmp_dir and the interim_dir
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remove_temp_files(tmp_dir)
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#remove_temp_files(int_dir)
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csv_names = [f for f in os.listdir(csv_output_dir) if f.endswith('.csv')]
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ch_limits = pd.read_excel(profile_limit_file, index_col='Profile')
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for csv_name in csv_names:
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profile_name = os.path.splitext(csv_name)[0]
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profiles = pd.read_csv(os.path.join(csv_output_dir, csv_name))
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# Remove metadata, and extract profile coordinates
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profiles = profiles.loc[:, 'Chainage':].set_index('Chainage')
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# Find landward limit of profile (behind beach)
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ch_min = ch_limits.loc[profile_name, 'Landward Limit']
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ax = plt.axes()
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for col in profiles.columns:
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profile = profiles.loc[ch_min:, col]
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date_str = col.split('_')[-1]
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date = '{}-{}-{}'.format(date_str[:4], date_str[4:6], date_str[6:])
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ax.plot(profile.index, profile, label=date)
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ax.set_xlabel('Chainage (m)', labelpad=10)
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ax.set_ylabel('Elevation (m AHD)', labelpad=10)
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ax.legend(frameon=False)
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plt.show()
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print("doing the volume analysis")
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# test=profile_plots_volume(csv_output_dir, profile_limit_file, volume_output, graph_loc)
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