1 | """Example of shallow water wave equation analytical solution of the |
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2 | circular hydraulic jump experimental data treated as a two-dimensional solution. |
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3 | |
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4 | Copyright 2005 |
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5 | Christopher Zoppou, Stephen Roberts |
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6 | Geoscience Australia, ANU |
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7 | """ |
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8 | |
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9 | #------------------------------- |
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10 | # Setup modules |
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11 | |
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12 | from anuga.shallow_water import Domain, Dirichlet_Discharge_boundary |
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13 | from anuga.shallow_water import Transmissive_Momentum_Set_Stage_boundary, Dirichlet_boundary |
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14 | from math import pi, sqrt |
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15 | from anuga.abstract_2d_finite_volumes.mesh_factory import strang_mesh |
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16 | |
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17 | |
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18 | #--------- |
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19 | # Geometry |
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20 | bed = ([.519, .519, .519, .519, .5192, .5194, .5196, .520, .5207, .5215, .5233, .5233]) |
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21 | distance = ([.08, .10, .11, .16, .21, .26, .31, .36, .41, .46, .50, .52]) |
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22 | n_bed = 12 |
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23 | |
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24 | #--------- |
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25 | # Case A.4 |
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26 | Q = 9.985/1000.0 |
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27 | wh0 = Q/(2.0*pi*0.1) |
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28 | stage0 = bed[2] + 0.005 |
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29 | wh1 = -Q/(2.0*pi*0.503) |
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30 | stage1 = 0.562 |
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31 | Manning = 0.009 |
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32 | |
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33 | #------------------ |
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34 | # Set up the domain |
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35 | # Strang_domain will search through the file and test to see if there are |
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36 | # two or three entries. Two entries are for points and three for triangles. |
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37 | points, elements = strang_mesh('circular.pt') |
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38 | domain = Domain(points, elements) |
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39 | |
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40 | print "Number of triangles = ", len(domain) |
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41 | |
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42 | #---------------------- |
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43 | # Set a default tagging |
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44 | |
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45 | |
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46 | for id, face in domain.boundary: |
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47 | domain.boundary[(id,face)] = 'outer' |
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48 | point = domain.get_vertex_coordinate(id,(face+1)%3) |
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49 | radius2 = point[0]*point[0] + point[1]*point[1] |
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50 | typical_outer = (id,face) |
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51 | if radius2 < 0.1: |
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52 | domain.boundary[(id,face)] = 'inner' |
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53 | typical_inner = (id,face) |
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54 | |
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55 | |
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56 | #------------------------------------- |
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57 | # Provide file name for storing output |
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58 | #domain.visualise = True |
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59 | domain.store = True |
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60 | domain.format = 'sww' |
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61 | domain.set_name('circular_second_order') |
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62 | |
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63 | #------------------------------------------ |
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64 | # Reduction operation for get_vertex_values |
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65 | from anuga.utilities.numerical_tools import mean |
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66 | #domain.reduction = mean |
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67 | #domain.reduction = min #Looks better near steep slopes |
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68 | |
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69 | #--------------------------- |
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70 | # Function for bed-elevation |
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71 | def bed_z(x,y): |
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72 | n = x.shape[0] |
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73 | z = 0*x |
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74 | for i in range(n): |
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75 | r = sqrt(x[i]*x[i]+y[i]*y[i]) |
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76 | for j in range(n_bed-1): |
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77 | if distance[j] <= r: |
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78 | if distance[j+1] > r: |
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79 | z[i] = bed[j] + (bed[j+1] - bed[j])/(distance[j+1] - distance[j])*(r - distance[j]) |
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80 | return z |
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81 | |
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82 | domain.set_quantity('elevation', bed_z) |
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83 | |
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84 | #--------- |
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85 | # Friction |
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86 | domain.set_quantity('friction', Manning) |
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87 | |
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88 | #--------------------------------- |
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89 | # Function for initial water elevation |
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90 | # (stage) |
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91 | def level(x,y): |
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92 | z = bed_z(x,y) |
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93 | n = x.shape[0] |
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94 | stage = 0*x |
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95 | for i in range(n): |
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96 | stage[i] = stage0 |
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97 | return stage |
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98 | |
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99 | |
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100 | #def outflow_stage(t): |
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101 | # return [stage1, 0 , 0] |
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102 | |
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103 | |
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104 | domain.set_quantity('stage', level) |
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105 | |
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106 | #--------------------------- |
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107 | # Set up boundary conditions |
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108 | DD_BC_INNER = Dirichlet_Discharge_boundary(domain, stage0, wh0) |
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109 | DD_BC_OUTER = Dirichlet_Discharge_boundary(domain, stage1, wh1) |
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110 | |
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111 | domain.set_boundary({'inner': DD_BC_INNER, 'outer': DD_BC_OUTER}) |
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112 | |
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113 | #------------------ |
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114 | # Order of accuracy |
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115 | domain.default_order = 2 |
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116 | domain.beta_w = 1.0 |
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117 | domain.beta_w_dry = 0.2 |
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118 | domain.beta_uh = 1.0 |
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119 | domain.beta_uh_dry = 0.2 |
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120 | domain.beta_vh = 1.0 |
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121 | domain.beta_vh_dry = 0.2 |
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122 | domain.CFL = 0.5 |
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123 | |
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124 | #domain.smooth = True |
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125 | |
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126 | |
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127 | # domain.initialise_visualiser() |
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128 | # domain.visualiser.coloring['stage'] = True |
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129 | # domain.visualiser.scale_z['stage'] = 2.0 |
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130 | # domain.visualiser.scale_z['elevation'] = 0.05 |
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131 | |
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132 | |
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133 | #domain.initialise_visualiser() |
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134 | # #domain.visualiser.coloring['stage'] = True |
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135 | #domain.visualiser.scale_z['stage'] = 2.0 |
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136 | #domain.visualiser.scale_z['elevation'] = 0.05 |
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137 | # |
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138 | # |
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139 | |
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140 | domain.initialise_visualiser() |
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141 | #from anuga.visualiser.vtk_realtime_visualiser import Visualiser |
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142 | |
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143 | #from realtime_visualisation_new import Visualiser |
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144 | #vis = Visualiser(domain,title="stage") |
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145 | #vis.setup['elevation'] = True |
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146 | #vis.updating['stage'] = True |
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147 | #vis.qcolor['stage'] = (0.0,0.0,0.8) |
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148 | #vis.coloring['stage']= True |
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149 | ##vxmom = Visualiser(domain,title='xmomentum',scale_z=10.0) |
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150 | ##vymom = Visualiser(domain,title='ymomentum',scale_z=10.0) |
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151 | |
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152 | stage = domain.quantities['stage'] |
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153 | |
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154 | #---------- |
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155 | # Evolution |
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156 | import time |
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157 | |
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158 | f = open("circular_hydraulic_jump_true.txt","w") |
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159 | |
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160 | t0 = time.time() |
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161 | for t in domain.evolve(yieldstep = .02, finaltime = 3.0): |
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162 | domain.write_time() |
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163 | #vis.update() |
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164 | exp = '(xmomentum**2 + ymomentum**2)**0.5' |
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165 | radial_momentum = domain.create_quantity_from_expression(exp) |
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166 | |
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167 | print 'outer stage ', stage.get_values(location='vertices', |
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168 | indices=[typical_outer[0]]) |
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169 | print ' radial mom ', \ |
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170 | radial_momentum.get_values(location='centroids', |
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171 | indices=[typical_outer[0]]) |
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172 | |
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173 | print 'inner stage ', stage.get_values(location='centroids', |
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174 | indices=[typical_inner[0]]) |
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175 | print ' radial mom ', \ |
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176 | radial_momentum.get_values(location='centroids', |
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177 | indices=[typical_inner[0]]) |
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178 | |
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179 | # f.write('time = %25.15e wall clock time %g \n' % (domain.time, time.time())) |
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180 | # f.write('%10.3f %25.15e %25.15e %25.15e %25.15e \n' % (domain.time, inner_stage, inner_radial_mom, outer_stage, outer_radial_mom)) |
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181 | |
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182 | f.write('time = %25.15e wall clock time %g \n' % (domain.time, time.time())) |
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183 | f.write('%g \n' % stage.get_values(location='centroids', |
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184 | indices=[typical_outer[0]])[0]) |
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185 | |
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186 | f.close() |
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187 | |
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188 | print 'That took %.2f seconds' %(time.time()-t0) |
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