def test_fun(self): edipath = EDI_DATA_DIR # path where edi files are located # period list (will not include periods outside of the range of the edi file) start_period = -2 stop_period = 3 n_periods = 17 period_list = np.logspace(start_period, stop_period, n_periods) # list of edi files, search for all files ending with '.edi' edi_list = [ os.path.join(edipath, ff) for ff in os.listdir(edipath) if (ff.endswith('.edi')) ] do = Data( edi_list=edi_list, inv_mode='1', save_path=self._output_dir, period_list=period_list, error_type_z='floor_egbert', error_value_z=5, error_type_tipper='floor_abs', error_value_tipper=.03, model_epsg=28354 # model epsg, currently set to utm zone 54 ) do.write_data_file() do.data_array['elev'] = 0. do.write_data_file(fill=False) # create model file mo = Model( station_locations=do.station_locations, cell_size_east=500, cell_size_north=500, pad_north= 7, # number of padding cells in each of the north and south directions pad_east=7, # number of east and west padding cells pad_z=6, # number of vertical padding cells pad_stretch_v= 1.6, # factor to increase by in padding cells (vertical) pad_stretch_h= 1.4, # factor to increase by in padding cells (horizontal) n_air_layers=10, # number of air layers res_model=100, # halfspace resistivity value for reference model n_layers=90, # total number of z layers, including air z1_layer=10, # first layer thickness pad_method='stretch', z_target_depth=120000) mo.make_mesh() mo.write_model_file(save_path=self._output_dir) # add topography to res model mo.add_topography_to_model2(AUS_TOPO_FILE) # mo.add_topography_to_model2(r'E:/Data/MT_Datasets/concurry_topo/AussieContinent_etopo1.asc') mo.write_model_file(save_path=self._output_dir) do.project_stations_on_topography(mo) co = Covariance() co.write_covariance_file(model_fn=mo.model_fn) for afile in ("ModEM_Data.dat", "covariance.cov", "ModEM_Model_File.rho"): output_data_file = os.path.normpath( os.path.join(self._output_dir, afile)) self.assertTrue(os.path.isfile(output_data_file), "output data file not found") expected_data_file = os.path.normpath( os.path.join(self._expected_output_dir, afile)) self.assertTrue( os.path.isfile(expected_data_file), "Ref output data file does not exist, nothing to compare with") # print ("Comparing", output_data_file, "and", expected_data_file) is_identical, msg = diff_files(output_data_file, expected_data_file) print msg self.assertTrue( is_identical, "The output file is not the same with the baseline file.")
10, #number of air layers, set to 0 to incorporate bathymetry only res_model=100, # halfspace resistivity value for reference model n_layers=100, # total number of z layers, including air z1_layer=10, # first layer thickness pad_method='stretch', # method for calculating padding z_mesh_method='new', z_target_depth= 120000 # depth to bottom of core model (padding after this depth) ) mo.make_mesh() mo.write_model_file(save_path=workdir) # Add topography from EDI data. # This function takes the same arguments as `add_topography_to_model2` # but instead of a DEM file it takes a Data object. mo.add_topography_from_data(do) mo.write_model_file(save_path=workdir) # update data elevations do.project_stations_on_topography(mo) # show the mesh mo.plot_sealevel_resistivity() co = Covariance() co.smoothing_east = 0.4 co.smoothing_north = 0.4 co.smoothing_z = 0.4 co.write_covariance_file(model_fn=mo.model_fn)
def test_fun_rotate(self): # set the dir to the output from the previously correct run self._expected_output_dir = os.path.join(SAMPLE_DIR, 'ModEM_rotate40') edipath = EDI_DATA_DIR2 # example to specify a number of periods per decade start_period = 0.002 stop_period = 2000 periods_per_decade = 4 period_list = get_period_list(start_period, stop_period, periods_per_decade, include_outside_range=True) # list of edi files, search for all files ending with '.edi' edi_list = [ os.path.join(edipath, ff) for ff in os.listdir(edipath) if (ff.endswith('.edi')) ] do = Data( edi_list=edi_list, inv_mode='1', save_path=self._output_dir, period_list=period_list, period_buffer= 2, # factor to stretch interpolation by. For example: if period_buffer=2 # then interpolated data points will only be included if they are # within a factor of 2 of a true data point error_type_z= 'floor_egbert', # error type (egbert is % of sqrt(zxy*zyx)) # floor means apply it as an error floor error_value_z=5, # error floor (or value) in percent error_type_tipper='floor_abs', # type of error to set in tipper, # floor_abs is an absolute value set as a floor error_value_tipper=.03, rotation_angle=40, model_epsg=28354 # model epsg, currently set to utm zone 54. # See http://spatialreference.org/ to find the epsg code for your projection ) do.write_data_file() do.data_array['elev'] = 0. do.write_data_file(fill=False) # mesh rotation angle is the opposite direction to the rotation of the stations if do.rotation_angle == 0: mesh_rotation_angle = 0 else: mesh_rotation_angle = -do.rotation_angle # create model file mo = Model( stations_object=do.station_locations, cell_size_east=8000, cell_size_north=8000, pad_north= 7, # number of padding cells in each of the north and south directions pad_east=7, # number of east and west padding cells pad_z=6, # number of vertical padding cells pad_stretch_v= 1.6, # factor to increase by in padding cells (vertical) pad_stretch_h= 1.4, # factor to increase by in padding cells (horizontal) n_air_layers=10, #number of air layers res_model=100, # halfspace resistivity value for reference model n_layers=100, # total number of z layers, including air z1_layer=10, # first layer thickness pad_method='stretch', # method for calculating padding z_mesh_method='new', z_target_depth= 120000, # depth to bottom of core model (padding after this depth) mesh_rotation_angle=mesh_rotation_angle) mo.make_mesh() mo.write_model_file(save_path=self._output_dir) # add topography to res model mo.add_topography_to_model2(AUS_TOPO_FILE) mo.write_model_file(save_path=self._output_dir) co = Covariance() co.smoothing_east = 0.4 co.smoothing_north = 0.4 co.smoothing_z = 0.4 co.write_covariance_file(model_fn=mo.model_fn) for afile in ("ModEM_Data.dat", "covariance.cov", "ModEM_Model_File.rho"): output_data_file = os.path.normpath( os.path.join(self._output_dir, afile)) self.assertTrue(os.path.isfile(output_data_file), "output data file not found") expected_data_file = os.path.normpath( os.path.join(self._expected_output_dir, afile)) self.assertTrue( os.path.isfile(expected_data_file), "Ref output data file does not exist, nothing to compare with") # print ("Comparing", output_data_file, "and", expected_data_file) is_identical, msg = diff_files(output_data_file, expected_data_file) print(msg) self.assertTrue( is_identical, "The output file is not the same with the baseline file.")
def build_modem_inputfiles(edi_path, output_path): """ For a given se to edi files in edi_path, build the ModEM input files into output_path :param edi_path: # path where edi files are located r'C:\mtpywin\mtpy\examples\data\edi_files_2' :param output_path: # path to save to r'C:\test\ModEM' :return: """ # not nece os.chdir(r'C:\mtpywin\mtpy') # change this path to the path where mtpy is installed ## period list (won't include periods outside of the range of the edi file) ### ## comment/uncomment your desired method ###################################### ############################################################################### ## example to specify start, stop and total number of periods # start_period = 0.001 # stop_period = 1000 # n_periods = 25 # period_list = np.logspace(np.log10(start_period), # np.log10(stop_period), # n_periods) # example to specify a number of periods per decade start_period = 0.002 stop_period = 2000 periods_per_decade = 4 period_list = get_period_list(start_period, stop_period, periods_per_decade, include_outside_range=True) ## an example to use the periods from a particular edi file # edifile_periods = op.join(edipath,'Synth00.edi') # eobj = Edi(edifile_periods) # period_list = 1./eobj.freq ############################################################################### workdir = output_path edipath = edi_path # list of edi files, search for all files ending with '.edi' edi_list = [ op.join(edipath, ff) for ff in os.listdir(edipath) if (ff.endswith('.edi')) ] # make the save path if it doesn't exist if not op.exists(workdir): os.mkdir(workdir) do = Data( edi_list=edi_list, inv_mode='1', save_path=workdir, period_list=period_list, period_buffer= 2, # factor to stretch interpolation by. For example: if period_buffer=2 # then interpolated data points will only be included if they are # within a factor of 2 of a true data point error_type_z=np.array([ ['floor_percent', 'floor_egbert'], # error type, options are 'egbert', 'percent', 'mean_od', 'eigen', 'median', 'off_diagonals' ['floor_egbert', 'percent'] ]), # add floor to apply it as an error floor # can supply a 2 x 2 array for each component or a single value error_value_z=np.array([ [20., 5.], # error floor value in percent [5., 20.] ]), # can supply a 2 x 2 array for each component or a single value error_type_tipper='floor_abs', # type of error to set in tipper, # floor_abs is an absolute value set as a floor error_value_tipper=.03, model_epsg=28354 # model epsg, currently set to utm zone 54. # See http://spatialreference.org/ to find the epsg code for your projection ) do.write_data_file() # set elevations to zero as we need to ensure the stations are on the topography do.data_array['elev'] = 0. do.write_data_file(fill=False) # create model file mo = Model( station_locations=do.station_locations, cell_size_east=8000, cell_size_north=8000, pad_north= 7, # number of padding cells in each of the north and south directions pad_east=7, # number of east and west padding cells pad_z=6, # number of vertical padding cells pad_stretch_v=1.6, # factor to increase by in padding cells (vertical) pad_stretch_h=1.4, # factor to increase by in padding cells (horizontal) pad_num= 3, # number of constant-width cells to add to outside of model before padding cells start # this number is currently multiplied by 1.5 internally n_air_layers= 10, # number of air layers, set to 0 to incorporate bathymetry only res_model=100, # halfspace resistivity value for reference model n_layers=100, # total number of z layers, including air z1_layer=10, # first layer thickness pad_method='stretch', # method for calculating padding z_mesh_method='new', z_target_depth= 120000 # depth to bottom of core model (padding after this depth) ) mo.make_mesh() mo.write_model_file(save_path=workdir) # add topography to res model # if the number of air layers is zero - bathymetry only will be added. # if the number of air layers is nonzero - topography will be added, discretised into that number of cells # mo.add_topography_to_model2(r'C:\mtpywin\mtpy\examples\data\AussieContinent_etopo1.asc') mo.add_topography_to_model2( r'C:\Githubz\mtpy\examples\data\AussieContinent_etopo1.asc') mo.write_model_file(save_path=workdir) # update data elevations do.project_stations_on_topography(mo) # show the mesh mo.plot_sealevel_resistivity() co = Covariance() co.smoothing_east = 0.4 co.smoothing_north = 0.4 co.smoothing_z = 0.4 co.write_covariance_file(model_fn=mo.model_fn)
data_fn = r'C:\mtpywin\mtpy\examples\model_files\ModEM\ModEM_Data.dat' dObj = Data() dObj.read_data_file(data_fn=data_fn) ### option 2 #### stationxyfile = r'C:\mtpywin\mtpy\examples\model_files\gocad\stationxy.txt' xy = np.loadtxt(stationxyfile, usecols=(1, 2)) station_names = np.loadtxt(stationxyfile, usecols=(0, ), dtype='S10') period_list = np.logspace(1, 4, 19) # change to your period list # create data file dObj = Data(epsg=epsg) dObj._initialise_empty_data_array(xy, period_list, location_type='LL', station_names=station_names) dObj.write_data_file(fill=False, save_path=workdir) # Create model file mObj = Model(Data=dObj, save_path=workdir) mObj.read_gocad_sgrid_file(gocad_sgrid_file) mObj.model_fn_basename = op.join(workdir, 'ModEM_Model_forward.ws') mObj.write_model_file() # create covariance file cov = Covariance(save_path=workdir, smoothing_east=0.3, smoothing_north=0.3, smoothing_z=0.3) cov.write_covariance_file(model_fn=mObj.model_fn)
def run(self): # monkey patch plt.show() so the plot is not displayed in worker thread true_plt_show = plt.show plt.show = _fake_plt_show self._figures = [] try: if not os.path.exists(self.output_dir): os.mkdir(self.output_dir) # get period_list list self.status_updated.emit("Selecting Periods...") period_list = EdiCollection(self._edi_list).select_periods(**self._select_period_kwargs) # save period plot for reference figure = plt.gcf() figure.savefig(os.path.join(self.output_dir, self._period_image_name)) if self.show: self.figure_updated.emit('Period Distribution', figure) # data object self.status_updated.emit("Creating ModEM Data Object...") self._data_kwargs['period_list'] = period_list data = Data(edi_list=self._edi_list, **self._data_kwargs) # write data file self.status_updated.emit("Writing Initial ModEM Data File...") data.write_data_file() # create model self.status_updated.emit("Creating Mesh Model...") model = Model(data_object=data, **self._mesh_kwagrs) model.make_mesh() # plot mesh model.plot_mesh(fig_num=plt.gcf().number + 1) figure = plt.gcf() figure.savefig(os.path.join(self.output_dir, self._mesh_image_name)) if self.show: self.figure_updated.emit("Mesh", figure) # model.plot_mesh_xy() # self.figure_updated.emit("Mesh XY", plt.gcf()) # model.plot_mesh_xz() # self.figure_updated.emit("Mesh XZ", plt.gcf()) model.write_model_file() # add topography self.status_updated.emit("Adding Topography...") model.add_topography_to_mesh(**self._topo_args) if self.show: model.plot_topograph() # this is too slow so only plot and save image when asked figure = plt.gcf() figure.savefig(os.path.join(self.output_dir, self._topo_image_name)) self.figure_updated.emit("Topography", figure) self.status_updated.emit("Updating Mesh Model...") model.write_model_file() # covariance self.status_updated.emit("Creating Covariance File...") self._covariance_kwargs['mask_arr'] = model.covariance_mask cov = Covariance(**self._covariance_kwargs) self.status_updated.emit("Writing Covariance File...") cov.write_covariance_file(model_fn=model.model_fn, sea_water=self._topo_args['sea_resistivity'], air=self._topo_args['air_resistivity']) self.status_updated.emit("Creating README File...") self.write_readme(os.path.join(self.output_dir, self._readme_name)) # done self.status_updated.emit("Finishing...") except Exception as e: frm = inspect.trace()[-1] mod = inspect.getmodule(frm[0]) self.export_error.emit("{}: {}".format(mod.__name__, e.message)) # restore plt.show() plt.show = true_plt_show
def test_fun_edi_elevation(self): edipath = EDI_DATA_DIR # path where edi files are located # set the dir to the output from the previously correct run self._expected_output_dir = os.path.join(SAMPLE_DIR, 'ModEM') # period list (will not include periods outside of the range of the edi file) start_period = -2 stop_period = 3 n_periods = 17 period_list = np.logspace(start_period, stop_period, n_periods) # list of edi files, search for all files ending with '.edi' edi_list = [ os.path.join(edipath, ff) for ff in os.listdir(edipath) if (ff.endswith('.edi')) ] do = Data( edi_list=edi_list, inv_mode='1', save_path=self._output_dir, period_list=period_list, error_type_z='floor_egbert', error_value_z=5, error_type_tipper='floor_abs', error_value_tipper=.03, model_epsg=28354 # model epsg, currently set to utm zone 54 ) do.write_data_file() # create model file mo = Model( station_locations=do.station_locations, cell_size_east=500, cell_size_north=500, pad_north= 7, # number of padding cells in each of the north and south directions pad_east=7, # number of east and west padding cells pad_z=6, # number of vertical padding cells pad_stretch_v= 1.6, # factor to increase by in padding cells (vertical) pad_stretch_h= 1.4, # factor to increase by in padding cells (horizontal) n_air_layers=10, # number of air layers res_model=100, # halfspace resistivity value for reference model n_layers=90, # total number of z layers, including air z1_layer=10, # first layer thickness pad_method='stretch', z_target_depth=120000) mo.make_mesh() mo.write_model_file(save_path=self._output_dir) # Add topography from EDI data mo.add_topography_from_data(do) mo.write_model_file(save_path=self._output_dir) # BM: note this function makes a call to `write_data_file` and this is the datafile being # compared! do.project_stations_on_topography(mo) co = Covariance() co.write_covariance_file(model_fn=mo.model_fn) # BM: if this test is failing check that the correct filenames are being selected # for comparison for test_output, expected_output in ( ("ModEM_Data_topo.dat", "ModEM_Data_EDI_elev.dat"), ("covariance.cov", "covariance_EDI_elev.cov"), ("ModEM_Model_File.rho", "ModEM_Model_File_EDI_elev.rho")): output_data_file = os.path.normpath( os.path.join(self._output_dir, test_output)) self.assertTrue(os.path.isfile(output_data_file), "output data file not found") expected_data_file = os.path.normpath( os.path.join(self._expected_output_dir, expected_output)) self.assertTrue( os.path.isfile(expected_data_file), "Ref output data file '{}' does not exist, nothing to compare with" .format(expected_data_file)) is_identical, msg = diff_files(output_data_file, expected_data_file) print(msg) self.assertTrue( is_identical, "The output file '{}' is not the same with the baseline file '{}'." .format(output_data_file, expected_data_file))