def test_get_domain_extent(self): domain_extent = get_domain_extent(3.5,5.0,1.0,2.5) self.assertAlmostEqual(domain_extent[0][0],-2.0) self.assertAlmostEqual(domain_extent[1][0], 2.0) self.assertAlmostEqual(domain_extent[0][1],-2.5) self.assertAlmostEqual(domain_extent[1][1], 2.5)
def compute_inputsToBeModified(temperature, flow_velocity, nb_pts_in_interface, ratio_interface_separation, ratio_bubble_interface, ratio_interface_influence, CFL_constant, total_nb_files, dct_distance, md_threshold_ac, md_threshold, flow_direction='x'): """Determine the inputs to be modified in the input.txt file for the simulation with two bubbles transported by the mean flow Args: temperature (double) : mean flow temperature flow_velocity (double) : mean flow velocity nb_pts_in_interface (int) : number of grid-points needed to resolve the interface profile ratio_interface_separation (double) : length (expressed as a fraction of the width of the interface) separating the two bubbles ratio_bubble_interface (double) : ratio between bubble diameter and interface width ratio_interface_influence (double) : length threshold (expressed as a fraction of the width of the interface) above which the interface is not supposed to interact with the border CFL_constant (double) : CFL threshold (0-1) total_nb_files (int) : total nb of files written dct_distance (int) : distance between the detectors and the boundary expressed as a number of gridpoints md_threshold_ac (int) : activate the increase of the computational domain with a mass density threshold md_threshold (double) : mass density threshold to activate the increase of the computational domain (between 0 and 1) Returns: inputsToBeModified (dict) : - dict[key] : name of the input to be modified - dict[value] : value of the input to be modified """ # extract length_c, dim2d_a, dim2d_b, dim2d_M, dim2d_cv, dim2d_R # and dim2d_K from the dim2d_parameters.f fortran file dim2dParamPath = os.path.join(os.getenv('augeanstables'), 'src', 'physical_models', 'dim2d', 'dim2d_parameters.f') if(os.path.isfile(dim2dParamPath)): length_c = float(get_parameter('length_c', dim2dParamPath)) dim2d_a = float(get_parameter( 'dim2d_a', dim2dParamPath)) dim2d_b = float(get_parameter( 'dim2d_b', dim2dParamPath)) dim2d_M = float(get_parameter( 'dim2d_M', dim2dParamPath)) dim2d_cv = float(get_parameter('dim2d_cv', dim2dParamPath)) dim2d_R = float(get_parameter( 'dim2d_R', dim2dParamPath)) dim2d_K = float(get_parameter( 'dim2d_K', dim2dParamPath)) else: sys.exit('*** '+dim2dParamPath+' does not exist***') # compute the Weber number we = get_we(length_c, dim2d_a, dim2d_b, dim2d_M, dim2d_K) # compute the interface length from the temperature interface_length = get_interface_length(we,temperature) # compute the bubble diameter bubble_diameter = interface_length*ratio_bubble_interface # compute the extent of the domain [Lx,Ly] = get_domain_sizes(bubble_diameter, interface_length, ratio_interface_influence, ratio_interface_separation) # compute the maximum space step from the interface length dx_max = get_interface_space_step(interface_length, nb_pts_in_interface) # get the extent of the domain # x_min : domain_extent[0][0] # x_max : domain_extent[1][0] # y_min : domain_extent[0][1] # y_max : domain_extent[1][1] domain_extent = get_domain_extent(Lx,Ly,dx_max,dx_max) # compute the reduced heat capacity cv_r = get_cv_r(dim2d_M,dim2d_cv,dim2d_R) # compute the maximum speed of sound in the flow speed_of_sound = get_max_speed_of_sound(temperature,cv_r) # compute the maximum time step ensuring numerical stability speed_max = speed_of_sound + abs(flow_velocity) dt_max = get_dt_max(dx_max,speed_max,CFL_constant) # determine the simulation time needed to let the two bubbles # leave the computational domain simulation_time = get_simulation_time(Lx, bubble_diameter, ratio_interface_separation*interface_length, ratio_interface_influence*interface_length, flow_velocity) # determine the detail print detail_print = get_detail_print(total_nb_files, simulation_time, dt_max) # gather the inputs to be modified in a dictionnary inputsToBeModified = { 'detail_print' : detail_print, 'dt' : dt_max, 't_max' : simulation_time, 'dx' : dx_max, 'dy' : dx_max, 'flow_velocity' : flow_velocity, 'temperature' : temperature, 'li_separation' : ratio_interface_separation, 'openbc_detector_distance' : dct_distance, 'openbc_md_threshold_ac' : md_threshold_ac, 'openbc_md_threshold' : md_threshold} if(flow_direction=='x'): inputsToBeModified.update({'x_min' : domain_extent[0][0], 'x_max' : domain_extent[1][0], 'y_min' : domain_extent[0][1], 'y_max' : domain_extent[1][1], 'flow_direction' : 'E'}) else: if(flow_direction!='y'): sys.exit('create_bb_tr_input: '+ 'compute_inputsToBeModified: '+ 'flow_direction not recognized') sys.exit(2) inputsToBeModified.update({'x_min' : domain_extent[0][1], 'x_max' : domain_extent[1][1], 'y_min' : domain_extent[0][0], 'y_max' : domain_extent[1][0], 'flow_direction' : 'N'}) return inputsToBeModified