source: anuga_work/development/saman_flume/run_dam.py @ 7244

Last change on this file since 7244 was 4444, checked in by duncan, 18 years ago

saman's flume
File size: 6.4 KB
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[4444]1"""Script for running a dam break simulation of UQ's dam break tank.
2
3
4Ole Nielsen and Duncan Gray, GA - 2006
5
6
7Issues
8If running this is hand-set-up parallel, the python files are overwritten.
9
10"""
11
12
13#----------------------------------------------------------------------------
14# Import necessary modules
15#----------------------------------------------------------------------------
16
17# Standard modules
18import time
19from time import localtime, strftime
20import sys
21from shutil import copy
22from os import path, sep
23from os.path import dirname  #, basename
24from math import tan, radians
25
26# Related major packages
27from anuga.shallow_water import Domain, Reflective_boundary, \
28                            Dirichlet_boundary, Time_boundary, File_boundary
29from anuga.abstract_2d_finite_volumes.region import Set_region
30from anuga.fit_interpolate.interpolate import interpolate_sww2csv
31from anuga.abstract_2d_finite_volumes.util import start_screen_catcher, \
32     copy_code_files
33
34
35# Scenario specific imports
36import project                 # Definition of file names and polygons
37import create_mesh
38
39
40
41def main(friciton,beach_angle, toe_to_nails_distance,
42         outputdir_name=None, is_trial_run=False):
43    """
44    beach angle is the angle in degrees of the sloped section
45    toe_to_nails_distance is the distance from the beginning if the sloped
46    section to the beginning of the nails section
47    """
48    basename = 'zz' + str(friction)
49    if is_trial_run is True:
50        outputdir_name += '_test'
51        yieldstep = 0.1
52        finaltime = 4
53    else:
54        yieldstep = 0.01
55        finaltime = 31
56    pro_instance = project.Project(['data','flumes','saman_2007'],
57                                       outputdir_name=outputdir_name)
58    mesh_filename = pro_instance.meshdir + basename + '.msh'
59
60    #--------------------------------------------------------------------------
61    # Copy scripts to output directory and capture screen
62    # output to file
63    #--------------------------------------------------------------------------
64
65    # creates copy of code in output dir
66    print "The output dir is", pro_instance.outputdir
67    copy_code_files(pro_instance.outputdir,__file__,
68                    dirname(project.__file__) \
69                    + sep + project.__name__+'.py')
70    copy (pro_instance.codedir + 'run_dam.py',
71          pro_instance.outputdir + 'run_dam' + str(friction)+ '.py')
72    copy (pro_instance.codedir + 'create_mesh.py',
73          pro_instance.outputdir + 'create_mesh.py')
74    copy (pro_instance.codedir + 'project.py',
75          pro_instance.outputdir + 'project.py')
76    if is_trial_run is False:
77        start_screen_catcher(pro_instance.outputdir, int(friction*100))
78
79    print 'USER:    ', pro_instance.user
80    #-------------------------------------------------------------------------
81    # Create the triangular mesh
82    #-------------------------------------------------------------------------
83   
84    #beach_angle = 15.0
85    #toe_to_nails_distance = .5
86    create_mesh.generate(mesh_filename,
87                         beach_angle,
88                         toe_to_nails_distance,
89                         is_coarse=is_trial_run) # this creates the mesh
90
91    head,tail = path.split(mesh_filename)
92    copy (mesh_filename,
93          pro_instance.outputdir + tail )
94    #-------------------------------------------------------------------------
95    # Setup computational domain
96    #-------------------------------------------------------------------------
97    domain = Domain(mesh_filename, use_cache = False, verbose = True)
98   
99
100    print 'Number of triangles = ', len(domain)
101    print 'The extent is ', domain.get_extent()
102    print domain.statistics()
103
104   
105    domain.set_name(basename)
106    domain.set_datadir(pro_instance.outputdir)
107    domain.set_quantities_to_be_stored(['stage', 'xmomentum', 'ymomentum'])
108    domain.set_minimum_storable_height(0.01)
109    #domain.set_store_vertices_uniquely(True)  # for writting to sww
110
111
112    def elevation_function(x,y):
113        from Numeric import zeros, size, Float
114        slope = create_mesh.xslope
115   
116        z = zeros(size(x), Float)
117        for i in range(len(x)):
118            if x[i] < slope:
119                z[i] = 0.0
120            else:
121                z[i] = (x[i]-slope)*tan(radians(beach_angle))
122        return z
123
124    #-------------------------------------------------------------------------
125    # Setup initial conditions
126    #-------------------------------------------------------------------------
127       
128    domain.set_quantity('stage', elevation_function)
129    domain.set_quantity('friction', friciton) 
130    domain.set_quantity('elevation', elevation_function)
131
132    print 'Available boundary tags', domain.get_boundary_tags()
133    domain.set_region('dam','stage',0.30,
134                                 location = 'unique vertices') 
135
136    Br = Reflective_boundary(domain)
137    Bd = Dirichlet_boundary([0,0,0])  # to drain the water out.
138    domain.set_boundary( {'wall': Br, 'edge': Bd} )
139
140    #-------------------------------------------------------------------------
141    # Evolve system through time
142    #-------------------------------------------------------------------------
143    t0 = time.time()
144
145    for t in domain.evolve(yieldstep, finaltime):
146        domain.write_time()
147   
148        print 'That took %.2f seconds' %(time.time()-t0)
149        print 'finished'
150
151
152    #-------------------------------------------------------------------------
153    # Calculate gauge info
154    #-------------------------------------------------------------------------
155    if not is_trial_run:
156        points = [[gate_position - 0.65,0.2],
157                  [gate_position - 0.55,0.2],
158                  [gate_position - 0.45,0.2],
159                  [gate_position - 0.35,0.2],
160                  [gate_position - 0.25,0.2]
161                  ]
162        interpolate_sww2csv(pro_instance.outputdir + basename +".sww",
163                            points,
164                            pro_instance.outputdir + \
165                            "depth_manning_"+str(friction)+".csv",
166                            pro_instance.outputdir + "velocity_x.csv",
167                            pro_instance.outputdir + "velocity_y.csv")
168 
169    return pro_instance
170
171#-------------------------------------------------------------
172if __name__ == "__main__":
173    beach_angle = 3.0
174    toe_to_nails_distance = 0.1
175    for friction in [0.0,0.01]:
176        main(friction,beach_angle, toe_to_nails_distance,
177             is_trial_run = True, outputdir_name='testing')
178   
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