source: anuga_work/development/friction_dam_2006/run_dam.py @ 6971

Last change on this file since 6971 was 4238, checked in by duncan, 18 years ago

more for updated urs2sww
File size: 6.2 KB
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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
24
25# Related major packages
26from anuga.shallow_water import Domain, Reflective_boundary, \
27                            Dirichlet_boundary, Time_boundary, File_boundary
28from anuga.abstract_2d_finite_volumes.region import Set_region
29from anuga.fit_interpolate.interpolate import interpolate_sww2csv
30from anuga.abstract_2d_finite_volumes.util import start_screen_catcher, \
31     copy_code_files
32
33
34# Scenario specific imports
35import project                 # Definition of file names and polygons
36import create_mesh
37
38
39def main(friction, outputdir_name=None, is_trial_run=False):
40    basename = 'zz' + str(friction)
41    if is_trial_run is True:
42        outputdir_name += '_test'
43        yieldstep = 1
44        finaltime = 31
45    else:
46        yieldstep = 0.01
47        finaltime = 31
48    pro_instance = project.Project(['data','flumes','dam_2006'],
49                                       outputdir_name=outputdir_name)
50    mesh_filename = pro_instance.meshdir + basename + '.msh'
51
52    #--------------------------------------------------------------------------
53    # Copy scripts to output directory and capture screen
54    # output to file
55    #--------------------------------------------------------------------------
56
57    # creates copy of code in output dir
58    print "The output dir is", pro_instance.outputdir
59    copy_code_files(pro_instance.outputdir,__file__,
60                    dirname(project.__file__) \
61                    + sep + project.__name__+'.py')
62    copy (pro_instance.codedir + 'run_dam.py',
63          pro_instance.outputdir + 'run_dam' + str(friction)+ '.py')
64    copy (pro_instance.codedir + 'create_mesh.py',
65          pro_instance.outputdir + 'create_mesh.py')
66    if is_trial_run is False:
67        start_screen_catcher(pro_instance.outputdir, int(friction*100))
68
69    print 'USER:    ', pro_instance.user
70    #-------------------------------------------------------------------------
71    # Create the triangular mesh
72    #-------------------------------------------------------------------------
73   
74    gate_position = 0.85
75    create_mesh.generate(mesh_filename,
76                         gate_position,
77                         is_coarse=is_trial_run) # this creates the mesh
78
79    head,tail = path.split(mesh_filename)
80    copy (mesh_filename,
81          pro_instance.outputdir + tail )
82    #-------------------------------------------------------------------------
83    # Setup computational domain
84    #-------------------------------------------------------------------------
85    domain = Domain(mesh_filename, use_cache = False, verbose = True)
86   
87
88    print 'Number of triangles = ', len(domain)
89    print 'The extent is ', domain.get_extent()
90    print domain.statistics()
91
92   
93    domain.set_name(basename)
94    domain.set_datadir(pro_instance.outputdir)
95    domain.set_quantities_to_be_stored(['stage', 'xmomentum', 'ymomentum'])
96    domain.set_minimum_storable_height(0.01)
97    #domain.set_store_vertices_uniquely(True)  # for writting to sww
98
99    #-------------------------------------------------------------------------
100    # Setup initial conditions
101    #-------------------------------------------------------------------------
102
103    slope = 0.05
104
105    def elevation_tilt(x, y):
106        return x*slope
107       
108    domain.set_quantity('stage', elevation_tilt)
109    domain.set_quantity('friction', friction) 
110    domain.set_quantity('elevation',elevation_tilt)
111
112    print 'Available boundary tags', domain.get_boundary_tags()
113    domain.set_region('dam','stage',0.20,
114                                 location = 'unique vertices') 
115    #domain.set_region(Set_region('dam','stage',0.2,
116    #                             location = 'unique vertices'))
117
118    Br = Reflective_boundary(domain)
119    Bd = Dirichlet_boundary([0,0,0])  # to drain the water out.
120    domain.set_boundary( {'wall': Br, 'edge': Bd} )
121
122    #-------------------------------------------------------------------------
123    # Evolve system through time
124    #-------------------------------------------------------------------------
125    t0 = time.time()
126
127    for t in domain.evolve(yieldstep, finaltime):
128        domain.write_time()
129   
130        print 'That took %.2f seconds' %(time.time()-t0)
131        print 'finished'
132
133    points = [[gate_position - 0.65,0.2],
134              [gate_position - 0.55,0.2],
135              [gate_position - 0.45,0.2],
136              [gate_position - 0.35,0.2],
137              [gate_position - 0.25,0.2]
138              ]
139
140    #-------------------------------------------------------------------------
141    # Calculate gauge info
142    #-------------------------------------------------------------------------
143
144    interpolate_sww2csv(pro_instance.outputdir + basename +".sww",
145                        points,
146                        pro_instance.outputdir + "depth_manning_"+str(friction)+".csv",
147                        pro_instance.outputdir + "velocity_x.csv",
148                        pro_instance.outputdir + "velocity_y.csv")
149 
150    return pro_instance
151
152#-------------------------------------------------------------
153if __name__ == "__main__":
154    for friction in [ 0.05]:
155        main(friction, is_trial_run = True, outputdir_name='friction_set_A')
156   
157    #    to do
158    # .075, -0-1
159    # 0.0075 - 0-16
160    #.01, - 0-2
161    #
162    #.0125, - 0-6
163    #0.015, - 0-17
164    #0.02, - 0-14
165    #$0.03]: - 0-7
166    # [0.016, - 0-11
167    #0.017, -0-8
168    #0.018, -0-9
169    #0.019]: - 0-12
170    # 0.005 - 0-20
171    # 0.02 - 4
172    # 0.016 - 8
173    # 0.017 - 9
174    # 0.018 - 1
175    # 0.019 -17
176    # calc - 7
177    # 0.0075 -12
178
179    # Let's fill some gaps
180    # 0.0225 - 7
181    # 0.025 - 12
182    # 0.0275 - 6
183    #for friction in [0.0, .0025, .005, .0075, .01, .0125, 0.015, 0.02, 0.03]:
184    #for friction in [0.016, 0.017, 0.018, 0.019]:
185    #    main(friction, is_trial_run = True, outputdir_name='friction_set')
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