1 | """Script for running a tsunami inundation scenario for Wollongong, NSW, Australia. |
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2 | |
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3 | Source data such as elevation and boundary data is assumed to be available in |
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4 | directories specified by project_slide.py |
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5 | The output sww file is stored in project_slide.outputtimedir |
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6 | |
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7 | The scenario is defined by a triangular mesh created from project.polygon, |
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8 | the elevation data and a tsunami wave generated by s submarine mass failure. |
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9 | |
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10 | Ole Nielsen and Duncan Gray, GA - 2005 and Nick Bartzis, GA - 2006 |
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11 | """ |
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12 | |
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13 | #------------------------------------------------------------------------------- |
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14 | # Import necessary modules |
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15 | #------------------------------------------------------------------------------- |
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16 | |
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17 | # Standard modules |
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18 | import os |
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19 | import time |
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20 | from shutil import copy |
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21 | from os.path import dirname, basename |
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22 | from os import mkdir, access, F_OK, sep |
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23 | import sys |
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24 | |
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25 | # Related major packages |
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26 | from anuga.shallow_water import Domain, Reflective_boundary, Dirichlet_boundary |
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27 | from anuga.shallow_water.data_manager import convert_dem_from_ascii2netcdf, dem2pts |
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28 | from anuga.geospatial_data.geospatial_data import * |
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29 | from anuga.abstract_2d_finite_volumes.util import start_screen_catcher, copy_code_files |
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30 | |
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31 | # Application specific imports |
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32 | import project_slide # Definition of file names and polygons |
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33 | |
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34 | #------------------------------------------------------------------------------- |
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35 | # Copy scripts to time stamped output directory and capture screen |
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36 | # output to file |
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37 | #------------------------------------------------------------------------------- |
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38 | |
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39 | # creates copy of code in output dir |
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40 | copy_code_files(project_slide.outputtimedir,__file__,dirname(project_slide.__file__)+sep+ project_slide.__name__+'.py' ) |
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41 | myid = 0 |
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42 | numprocs = 1 |
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43 | start_screen_catcher(project_slide.outputtimedir, myid, numprocs) |
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44 | |
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45 | print 'USER: ', project_slide.user |
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46 | |
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47 | #------------------------------------------------------------------------------- |
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48 | # Preparation of topographic data |
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49 | # |
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50 | # Convert ASC 2 DEM 2 PTS using source data and store result in source data |
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51 | #------------------------------------------------------------------------------- |
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52 | |
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53 | # filenames |
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54 | on_offshore10_dem_name = project_slide.on_offshore10_dem_name |
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55 | nsw_dem_name = project_slide.nsw_dem_name |
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56 | meshname = project_slide.meshname+'.msh' |
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57 | |
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58 | # creates DEM from asc data |
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59 | convert_dem_from_ascii2netcdf(on_offshore10_dem_name, use_cache=True, verbose=True) |
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60 | convert_dem_from_ascii2netcdf(nsw_dem_name, use_cache=True, verbose=True) |
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61 | |
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62 | #creates pts file for onshore DEM |
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63 | dem2pts(on_offshore10_dem_name, use_cache=True, verbose=True) |
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64 | dem2pts(nsw_dem_name, |
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65 | easting_min=project_slide.eastingmin_nsw, |
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66 | easting_max=project_slide.eastingmax_nsw, |
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67 | northing_min=project_slide.northingmin_nsw, |
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68 | northing_max= project_slide.northingmax_nsw, |
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69 | use_cache=True, verbose=True) |
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70 | |
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71 | print 'create offshore' |
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72 | G11 = Geospatial_data(file_name = project_slide.offshore_dem_name1 + '.xya') |
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73 | G12 = Geospatial_data(file_name = project_slide.offshore_dem_name4 + '.xya')+\ |
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74 | Geospatial_data(file_name = project_slide.offshore_dem_name5 + '.xya')+\ |
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75 | Geospatial_data(file_name = project_slide.offshore_dem_name6 + '.xya')+\ |
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76 | Geospatial_data(file_name = project_slide.offshore_dem_name7 + '.xya')+\ |
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77 | Geospatial_data(file_name = project_slide.offshore_dem_name8 + '.xya')+\ |
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78 | Geospatial_data(file_name = project_slide.offshore_dem_name9 + '.xya') |
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79 | print 'create onshore' |
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80 | G2 = Geospatial_data(file_name = project_slide.on_offshore10_dem_name + '.pts') |
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81 | G4 = Geospatial_data(file_name = project_slide.nsw_dem_name + '.pts') |
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82 | print 'add' |
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83 | G = G11.clip(Geospatial_data(project_slide.poly_surveyclip)) +\ |
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84 | G12.clip(Geospatial_data(project_slide.polyAll)) +\ |
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85 | G2.clip(Geospatial_data(project_slide.poly_10mclip)) +\ |
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86 | (G4.clip(Geospatial_data(project_slide.polyAll))).clip_outside(Geospatial_data(project_slide.poly_surveyclip)).clip_outside(Geospatial_data(project_slide.poly_10mclip)) |
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87 | print 'export points' |
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88 | G.export_points_file(project_slide.combined_dem_name + '.pts') |
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89 | #G.export_points_file(project_slide.combined_dem_name + '.xya') |
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90 | |
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91 | #---------------------------------------------------------------------------- |
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92 | # Create the triangular mesh based on overall clipping polygon with a tagged |
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93 | # boundary and interior regions defined in project.py along with |
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94 | # resolutions (maximal area of per triangle) for each polygon |
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95 | #------------------------------------------------------------------------------- |
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96 | |
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97 | from anuga.pmesh.mesh_interface import create_mesh_from_regions |
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98 | remainder_res = 100000 |
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99 | local_res = 25000 |
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100 | gong_res = 500 |
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101 | interior_regions = [[project_slide.poly_local, local_res], |
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102 | [project_slide.poly_gong, gong_res], |
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103 | [project_slide.poly_southgong, gong_res]] |
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104 | |
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105 | from caching import cache |
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106 | _ = cache(create_mesh_from_regions, |
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107 | project_slide.polyAll, |
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108 | {'boundary_tags': {'e0': [0], 'e1': [1], 'e2': [2], |
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109 | 'e3': [3], 'e4':[4]}, |
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110 | 'maximum_triangle_area': remainder_res, |
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111 | 'filename': meshname, |
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112 | 'interior_regions': interior_regions}, |
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113 | verbose = True, evaluate=False) |
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114 | print 'created mesh' |
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115 | |
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116 | #------------------------------------------------------------------------------- |
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117 | # Setup computational domain |
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118 | #------------------------------------------------------------------------------- |
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119 | domain = Domain(meshname, use_cache = True, verbose = True) |
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120 | |
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121 | print 'Number of triangles = ', len(domain) |
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122 | print 'The extent is ', domain.get_extent() |
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123 | print domain.statistics() |
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124 | |
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125 | domain.set_name(project_slide.basename) |
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126 | domain.set_datadir(project_slide.outputtimedir) |
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127 | domain.set_quantities_to_be_stored(['stage', 'xmomentum', 'ymomentum']) |
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128 | domain.set_minimum_storable_height(0.01) |
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129 | |
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130 | #------------------------------------------------------------------------------- |
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131 | # Setup initial conditions |
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132 | #------------------------------------------------------------------------------- |
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133 | |
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134 | tide = 0.0 |
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135 | domain.set_quantity('stage', tide) |
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136 | domain.set_quantity('friction', 0.0) |
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137 | domain.set_quantity('elevation', |
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138 | filename = project_slide.combined_dem_name + '.pts', |
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139 | use_cache = True, |
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140 | verbose = True, |
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141 | alpha = 0.1 |
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142 | ) |
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143 | |
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144 | #------------------------------------------------------------------------------- |
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145 | # Set up scenario (tsunami_source is a callable object used with set_quantity) |
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146 | #------------------------------------------------------------------------------- |
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147 | from smf import slide_tsunami |
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148 | |
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149 | tsunami_source = slide_tsunami(length=project_slide.bulli_length, |
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150 | width=project_slide.bulli_width, |
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151 | depth=project_slide.bulli_depth, |
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152 | slope=project_slide.bulli_slope, |
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153 | thickness=project_slide.bulli_thickness, |
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154 | x0=project_slide.slide_origin_a[0], |
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155 | y0=project_slide.slide_origin_a[1], |
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156 | alpha=project_slide.bulli_alpha, |
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157 | domain=domain) |
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158 | |
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159 | #------------------------------------------------------------------------------- |
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160 | # Setup boundary conditions |
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161 | #------------------------------------------------------------------------------- |
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162 | print 'Available boundary tags', domain.get_boundary_tags() |
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163 | |
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164 | Br = Reflective_boundary(domain) |
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165 | Bd = Dirichlet_boundary([tide,0,0]) |
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166 | |
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167 | domain.set_boundary( {'e0': Bd, 'e1': Bd, 'e2': Bd, 'e3': Bd, 'e4': Bd} ) |
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168 | |
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169 | |
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170 | #------------------------------------------------------------------------------- |
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171 | # Evolve system through time |
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172 | #------------------------------------------------------------------------------- |
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173 | import time |
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174 | t0 = time.time() |
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175 | from Numeric import allclose |
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176 | from anuga.abstract_2d_finite_volumes.quantity import Quantity |
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177 | |
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178 | for t in domain.evolve(yieldstep = 30, finaltime = 5000): |
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179 | domain.write_time() |
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180 | domain.write_boundary_statistics(tags = 'e14') |
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181 | stagestep = domain.get_quantity('stage') |
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182 | |
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183 | if allclose(t, 30): |
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184 | slide = Quantity(domain) |
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185 | slide.set_values(tsunami_source) |
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186 | domain.set_quantity('stage', slide + stagestep) |
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187 | |
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188 | print 'That took %.2f seconds' %(time.time()-t0) |
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189 | |
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190 | print 'finished' |
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