source: production/onslow_2006/run_onslow_new.py @ 3241

Last change on this file since 3241 was 2615, checked in by nick, 19 years ago

update onslow

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1"""Script for running a tsunami inundation scenario for Onslow, WA, Australia.
2
3Source data such as elevation and boundary data is assumed to be available in
4directories specified by project.py
5The output sww file is stored in project.outputdir
6
7The scenario is defined by a triangular mesh created from project.polygon,
8the elevation data and a simulated submarine landslide.
9
10Ole Nielsen and Duncan Gray, GA - 2005 and Nick Bartzis, GA - 2006
11"""
12
13
14#-------------------------------------------------------------------------------# Import necessary modules
15#-------------------------------------------------------------------------------
16
17# Standard modules
18import os
19import time
20
21# Related major packages
22from pyvolution.shallow_water import Domain, Reflective_boundary, \
23                            Dirichlet_boundary, Time_boundary, File_boundary
24from pyvolution.data_manager import convert_dem_from_ascii2netcdf, dem2pts
25from pyvolution.combine_pts import combine_rectangular_points_files
26from pyvolution.pmesh2domain import pmesh_to_domain_instance
27from geospatial_data import add_points_files
28
29# Application specific imports
30import project                 # Definition of file names and polygons
31from smf import slump_tsunami  # Function for submarine mudslide
32
33from shutil import copy
34from os import mkdir, access, F_OK
35
36from geospatial_data import *
37
38#-------------------------------------------------------------------------------
39# Preparation of topographic data
40#
41# Convert ASC 2 DEM 2 PTS using source data and store result in source data
42# Do for coarse and fine data
43# Fine pts file to be clipped to area of interest
44#-------------------------------------------------------------------------------
45
46# filenames
47coarsedemname = project.coarsedemname
48
49onshore_dem_name = project.onshore_dem_name
50
51offshore_points = project.offshore_dem_name
52
53meshname = project.meshname+'.msh'
54
55source_dir = project.boundarydir
56
57# creates copy of code in output dir
58if access(project.outputdir,F_OK) == 0 :
59    mkdir (project.outputdir)
60copy (project.codedirname, project.outputdir + project.codename)
61copy (project.codedir + 'run_onslow.py', project.outputdir + 'run_onslow.py')
62
63
64'''
65# coarse data
66convert_dem_from_ascii2netcdf(coarsedemname, use_cache=True, verbose=True)
67dem2pts(coarsedemname, use_cache=True, verbose=True)
68
69
70# fine data (clipping the points file to smaller area)
71convert_dem_from_ascii2netcdf(onshore_dem_name, use_cache=True, verbose=True)
72dem2pts(onshore_dem_name,
73        easting_min=project.eastingmin,
74        easting_max=project.eastingmax,
75        northing_min=project.northingmin,
76        northing_max= project.northingmax,
77        use_cache=True,
78        verbose=True)
79
80        '''
81print'create G1'
82G1 = Geospatial_data(file_name = project.offshore_dem_name + '.xya')
83
84print'create G2'
85G2 = Geospatial_data(file_name = project.onshore_dem_name + '.pts')
86
87print'add G1+G2'
88G = G1 + G2
89
90print'export G'
91G.new_export_points_file(project.combined_dem_name + '.pts')
92
93'''
94add_points_files(
95                  project.offshore_dem_name + '.xya',
96                  project.onshore_dem_name + '.pts',
97                  project.combined_dem_name + '.pts')
98'''
99#-------------------------------------------------------------------------------                                 
100# Create the triangular mesh based on overall clipping polygon with a tagged
101# boundary and interior regions defined in project.py along with
102# resolutions (maximal area of per triangle) for each polygon
103#-------------------------------------------------------------------------------
104
105from pmesh.mesh_interface import create_mesh_from_regions
106
107# original
108interior_res = 5000
109interior_regions = [[project.poly_onslow, interior_res],
110                    [project.poly_thevenard, interior_res],
111                    [project.poly_direction, interior_res]]
112                    #[project.testpoly, interior_res]]
113print 'number of interior regions', len(interior_regions)
114
115from caching import cache
116_ = cache(create_mesh_from_regions,
117          project.polyAll,
118          {'boundary_tags': {'top': [0], 'topleft': [1],
119                             'left': [2], 'bottom': [3],
120                             'bottomright': [4], 'topright': [5]},
121           'maximum_triangle_area': 100000,
122           'filename': meshname,           
123           'interior_regions': interior_regions},
124          verbose = True)
125
126
127#-------------------------------------------------------------------------------                                 
128# Setup computational domain
129#-------------------------------------------------------------------------------                                 
130
131domain = pmesh_to_domain_instance(meshname, Domain,
132                                  use_cache = True,
133                                  verbose = True)
134
135print 'Number of triangles = ', len(domain)
136print 'The extent is ', domain.get_extent()
137print domain.statistics()
138
139domain.set_name(project.basename)
140domain.set_datadir(project.outputdir)
141domain.set_quantities_to_be_stored(['stage'])
142
143
144#-------------------------------------------------------------------------------
145# Set up scenario (tsunami_source is a callable object used with set_quantity)
146#-------------------------------------------------------------------------------
147'''
148tsunami_source = slump_tsunami(length=30000.0,
149                               depth=400.0,
150                               slope=6.0,
151                               thickness=176.0,
152                               radius=3330,
153                               dphi=0.23,
154                               x0=project.slump_origin[0],
155                               y0=project.slump_origin[1],
156                               alpha=0.0,
157                               domain=domain)
158
159'''
160#-------------------------------------------------------------------------------                                 
161# Setup initial conditions
162#-------------------------------------------------------------------------------
163
164tide = 0.
165
166domain.set_quantity('stage', tide)
167domain.set_quantity('friction', 0.0) 
168print 'hi and file',project.combined_dem_name + '.pts'
169domain.set_quantity('elevation', 
170#                    0.
171#                    filename = project.onshore_dem_name + '.pts',
172                    filename = project.combined_dem_name + '.pts',
173#                    filename = project.offshore_dem_name + '.pts',
174                    use_cache = False,
175                    verbose = True,
176                    alpha = 0.1
177                    )
178print 'hi1'
179
180#-------------------------------------------------------------------------------                                 
181# Setup boundary conditions (all reflective)
182#-------------------------------------------------------------------------------
183
184from pyvolution.data_manager import ferret2sww
185
186south = project.south
187north = project.north
188west = project.west
189east = project.east
190
191cache(ferret2sww,
192      (source_dir + project.boundary_basename,
193       source_dir + project.boundary_basename), 
194      {'verbose': True,
195# note didn't work with the below
196#       'minlat': south - 1,
197#       'maxlat': north + 1,
198#       'minlon': west - 1,
199#       'maxlon': east + 1,
200       'minlat': south,
201       'maxlat': north,
202       'minlon': west,
203       'maxlon': east,
204#       'origin': project.mesh_origin,
205       'origin': domain.geo_reference.get_origin(),
206       'mean_stage': tide,
207       'zscale': 1,                 #Enhance tsunami
208       'fail_on_NaN': False,
209       'inverted_bathymetry': True},
210      #evaluate = True,
211       verbose = True)
212
213
214print 'Available boundary tags', domain.get_boundary_tags()
215
216Bf = File_boundary(source_dir + project.boundary_basename + '.sww', 
217                    domain, verbose = True)
218Br = Reflective_boundary(domain)
219Bd = Dirichlet_boundary([tide,0,0])
220
221
222# 7 min square wave starting at 1 min, 6m high
223Bw = Time_boundary(domain = domain,
224                   f=lambda t: [(60<t<480)*6, 0, 0])
225
226domain.set_boundary( {'top': Bf, 'topleft': Bf,
227                             'left': Br, 'bottom': Br,
228                             'bottomright': Br, 'topright': Bf} )
229
230
231#-------------------------------------------------------------------------------                                 
232# Evolve system through time
233#-------------------------------------------------------------------------------
234import time
235t0 = time.time()
236
237for t in domain.evolve(yieldstep = 50, finaltime = 100): 
238    domain.write_time()
239    domain.write_boundary_statistics(tags = 'top')     
240   
241print 'That took %.2f seconds' %(time.time()-t0)
242
243print 'finished'
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