def write_numeric_file_numpy(file_name, data_array): (path_file_local, path_name_local) = os.path.split(file_name) print_message('Writing file: ' + str(path_name_local)) if not os.path.exists(path_file_local): os.mkdir(path_file_local) np.savetxt(file_name, data_array) print_message('Writing file: ' + str(path_name_local) + " - Done!")
def write_numeric_file_numpy(file_name, data_array): (path_file_local,path_name_local)=os.path.split(file_name) print_message('Writing file: '+str(path_name_local)) if not os.path.exists(path_file_local): os.mkdir(path_file_local) np.savetxt(file_name,data_array) print_message('Writing file: '+str(path_name_local)+" - Done!")
def write_file (file_name,file_data,key,clear_document): ''' Write a txt file\n file_name: The complete directory+file name\n file_data: A list containing the data to write\n key: The block key - if key="", block structure is not created\n clear_document: bool (clear the previous document?) ''' (path_file_local,path_name_local)=os.path.split(file_name) print_message('Writing file: '+str(path_name_local)) if not os.path.exists(path_file_local): os.mkdir(path_file_local) if clear_document: file_open_mode="w" else: file_open_mode="a" try: f = open(file_name, file_open_mode) try: if key!='': f.writelines('$'+key+'\n') # Write a string to a file for each_line in file_data: each_line=str(each_line) each_line=each_line.replace("]","") each_line=each_line.replace("[","") f.write(str(each_line)+'\n') if key!='': f.write('$End'+key+"\n") # Write a string to a file finally: f.close() print_message('Writing file: '+str(path_name_local) +"- Done!") except IOError: pass
def write_file(file_name, file_data, key, clear_document): ''' Write a txt file\n file_name: The complete directory+file name\n file_data: A list containing the data to write\n key: The block key - if key="", block structure is not created\n clear_document: bool (clear the previous document?) ''' (path_file_local, path_name_local) = os.path.split(file_name) print_message('Writing file: ' + str(path_name_local)) if not os.path.exists(path_file_local): os.mkdir(path_file_local) if clear_document: file_open_mode = "w" else: file_open_mode = "a" try: f = open(file_name, file_open_mode) try: if key != '': f.writelines('$' + key + '\n') # Write a string to a file for each_line in file_data: each_line = str(each_line) each_line = each_line.replace("]", "") each_line = each_line.replace("[", "") f.write(str(each_line) + '\n') if key != '': f.write('$End' + key + "\n") # Write a string to a file finally: f.close() print_message('Writing file: ' + str(path_name_local) + "- Done!") except IOError: pass
def SolveMagneticCircuit(Ac, Yb, F, J, BC_nodes, BC_values): print_message("Running circuit solver") flux = __solve_nodal_circuit(Ac, Yb, F, J, BC_nodes, BC_values) # flux=solve_nodal_circuit_diagonal(Ac,Yb, F) print_message("Running circuit solver - Done") return flux
def integration_process(folder_path,preProcData): file_names=File_names() results_folder=file_names.get_results_folder_name() results_path=os.path.join(folder_path,results_folder) #%% Instances and geral definitions aux_RNM=AuxMethodsRNM() global_variables=GlobalVariables() error=Errors() operations=Operations() materials_lib=get_materials_lib() vacuum=Vacuum() get_gauss_points_class=GaussPoints() shape_functions=ShapeFuncions() operations=Operations() str_noflux_face=global_variables.str_noflux_face open_circuit_reluctance=global_variables.magnetic_open_circuit_reluctance results_folder=file_names.get_results_folder_name() face=Face() #------------------------------------------------------------------------------ # Setup regions_material=preProcData.RegionMaterial regions_excitation=preProcData.RegionExcitation boundary=preProcData.BC external_reluctances=preProcData.ExternalReluctances coupling=preProcData.CoupNet #------------------------------------------------------------------------------ # Mesh mesh_data=preProcData.MeshData all_elem_nodes_3D= mesh_data.ElemNodes nodes_coordenates=mesh_data.NodesCoordenates elem_tags=mesh_data.ElemTags elem_type=mesh_data.ElemType #%%Get source field #Run Biot-Savart run_biot_savart=False # for eachregion in regions_excitation: # if eachregion.Value != 0.0: # field_solution=Biot_Savart.run_Biot_Savart(setup_file_name,mesh_file_name,folder_path) # run_biot_savart=True # break # Run Permanent Magnets run_permanent_magnets=False for each_region in regions_material: for each in materials_lib[each_region.MaterialName].Hc: if each !=0.0: field_solution=permanent_magnets.run_permanent_magnets(preProcData,folder_path) run_permanent_magnets=True break #Read the file if run_biot_savart or run_permanent_magnets: (H_field,H_field_elem_nodes_3D)=get_Field_solution(os.path.join(results_path,file_names.get_H_results_file_name())) run_external_circuit=False if len(coupling)>0: run_external_circuit=True #%% Get 2D and 3D elements, with their materials name elem_2D_ID=list() elem_type_3D=list() elem_nodes_3D=list() elem_tags_3D=list() region_ID_list_3D=list() number_elements_2D=0 for counter,each_elem in enumerate(all_elem_nodes_3D): this_elem_type=elem_type[counter] if this_elem_type<4: elem_2D_ID.append(counter) number_elements_2D+=1 else: elem_nodes_3D.append(each_elem) elem_type_3D.append(elem_type[counter]) elem_tags_3D.append(elem_tags[counter]) find=False for each_region in regions_material: if each_region.RegionNumber==elem_tags[counter][0]: region_ID_list_3D.append(each_region.MaterialName) find=True if not find: error.physical_surface_not_defined(str(each_region.RegionNumber),elem_tags[counter][0]) number_elements=len(elem_nodes_3D) number_nodes=len(nodes_coordenates) faces_ID=list() faces_list=list() #%%Creates the face list print_message("Creating faces list") for elem_counter in range(0,number_elements): number_local_faces=shape_functions.get_number_faces(this_elem_type) this_elem_type=elem_type_3D[elem_counter] this_element_nodes=elem_nodes_3D[elem_counter] faces_nodes_ID=shape_functions.get_nodes_ID_2_face(this_elem_type) number_faces,nodes_per_face=faces_nodes_ID.shape local_faces_ID=list() for local_face_counter in range(0,number_faces): nodes_list=list() for node_counter in range(nodes_per_face): node_ID=faces_nodes_ID[local_face_counter,node_counter] nodes_list.append(this_element_nodes[node_ID]) local_faces_ID.append(face.add_to_list(nodes_list,elem_counter,faces_list)) faces_ID.append(local_faces_ID) print_message("Creating faces list - Done") #%%Integration print_message("Integration process") num_meshed_rel=len(faces_list) num_non_meshed_rel=len(external_reluctances) num_total_rel=num_meshed_rel+num_non_meshed_rel #sparse matrix cols_rel_sparse=list() rows_rel_sparse=list() #reluctance matrix diagonal=list() for each_element_faces in faces_ID: numbre_faces_this_element=len(each_element_faces) for face_counter_1 in xrange(numbre_faces_this_element): pos_1=each_element_faces[face_counter_1] for face_counter_2 in xrange(numbre_faces_this_element): pos_2=each_element_faces[face_counter_2] if faces_list[pos_1].elem_2!=str_noflux_face and faces_list[pos_1].elem_2!=str_noflux_face: if pos_1==pos_2: if pos_1 not in diagonal: rows_rel_sparse.append(pos_1) cols_rel_sparse.append(pos_2) diagonal.append(pos_1) else: rows_rel_sparse.append(pos_1) cols_rel_sparse.append(pos_2) data_rel_sparse=np.zeros(len(rows_rel_sparse)) faces_rel_spare=csr_matrix((data_rel_sparse, (rows_rel_sparse, cols_rel_sparse)), shape=(num_meshed_rel, num_meshed_rel)) #fmm matrix cols_fmm_sparse=np.zeros(num_meshed_rel) rows_fmm_sparse=xrange(0,num_meshed_rel) data_fmm_sparse=np.zeros(num_meshed_rel) fmm_sparse=csr_matrix((data_fmm_sparse, (rows_fmm_sparse, cols_fmm_sparse)), shape=(num_meshed_rel,1)) faces_rel_matrix=np.zeros((num_meshed_rel,num_meshed_rel)) faces_fmm_matrix=np.zeros((num_meshed_rel,1)) xy_integ_points_list=list() W_integ_points_list=list() this_elem_type="" for elem_counter in xrange(number_elements): this_elem_type_changed=elem_type_3D[elem_counter] if this_elem_type!=this_elem_type_changed: this_elem_type=this_elem_type_changed gauss_points=get_gauss_points_class.get_gauss_points(this_elem_type) number_local_faces=shape_functions.get_number_faces(this_elem_type) number_integ_points=len(get_gauss_points_class.get_gauss_points(this_elem_type)) wtri=get_gauss_points_class.get_integration_weight(this_elem_type) faces_ID_Elem=faces_ID[elem_counter] this_element_nodes=elem_nodes_3D[elem_counter] mu_elem=vacuum.mu0*materials_lib[region_ID_list_3D[elem_counter]].Permeability # Get W at reference element w_local_this_element=list() #[gauss point][face] for each_integ_point in xrange(number_integ_points): #u,v,w coordinates u=gauss_points[each_integ_point,0] v=gauss_points[each_integ_point,1] w=gauss_points[each_integ_point,2] # Shape functions @ reference element w_local_this_point=shape_functions.get_facet_shape_function(this_elem_type,u,v,w) w_local_this_element.append(w_local_this_point) # Shape functions @ real element for each face w_real_all_points=list() # w_real_lista[0] contains the shape function of all points for face 0 # Face 0...Fn #P0 W #Pn for face_counter in xrange(number_local_faces): w_real_this_point=list() for point_counter in range(0,number_integ_points): w_local=w_local_this_element[point_counter][face_counter] w_real=operations.convert_local_real_Piola(this_elem_type,w_local[0,0],w_local[0,1],w_local[0,2],this_element_nodes,nodes_coordenates) w_real_this_point.append(w_real) w_real_all_points.append(w_real_this_point) # Source fields if run_biot_savart or run_permanent_magnets: H_points=H_field_elem_nodes_3D[elem_counter] for local_face_counter in xrange(number_local_faces): w_1=copy.deepcopy(w_real_all_points[local_face_counter]) face_ID_1=faces_ID_Elem[local_face_counter] if faces_list[face_ID_1].elem_2==elem_counter: for each in w_1: each=aux_RNM.invert_w(each) # mmf source integration process source=0 for each_integ_point in xrange(number_integ_points): w_1_this_point=w_1[each_integ_point] u=gauss_points[each_integ_point,0] v=gauss_points[each_integ_point,1] p=gauss_points[each_integ_point,2] w=w_1_this_point xy_coord=operations.convert_local_real(this_elem_type,u,v,p,this_element_nodes,nodes_coordenates) xy_integ_points_list.append(xy_coord) W_integ_points_list.append(w) if run_biot_savart or run_permanent_magnets: H_point=H_points[each_integ_point] Hx=H_field[H_point][0] Hy=H_field[H_point][1] Hz=H_field[H_point][2] if (Hx!=0) or (Hy!=0) or (Hz!=0) : Hxy=np.array([[Hx], [Hy], [Hz]]) # Jacobian jac=operations.get_jacobian(this_elem_type,this_element_nodes,nodes_coordenates,u,v) det_jac=np.linalg.det(jac) abs_det_jac=np.abs(det_jac) source=source+wtri*abs_det_jac*aux_RNM.dot_product(w,Hxy) aux_RNM.fmm_matrix_control(face_ID_1,faces_fmm_matrix,source,False,faces_list,str_noflux_face) aux_RNM.fmm_matrix_control(face_ID_1,fmm_sparse,source,False,faces_list,str_noflux_face) fmm_sparse # Relutances integration process for local_face_counter_2 in xrange(number_local_faces): w_2=copy.deepcopy(w_real_all_points[local_face_counter_2]) face_ID_2=faces_ID_Elem[local_face_counter_2] if faces_list[face_ID_2].elem_2==elem_counter: for each in w_2: each=aux_RNM.invert_w(each) wtot=0.0 for each_integ_point in range(0,number_integ_points): u=gauss_points[each_integ_point,0] v=gauss_points[each_integ_point,1] p=gauss_points[each_integ_point,2] # Jacobian jac=operations.get_jacobian(this_elem_type,this_element_nodes,nodes_coordenates,u,v,p) det_jac=np.linalg.det(jac) abs_det_jac=np.abs(det_jac) # Reluctance w_1_this_point=w_1[each_integ_point] w_2_this_point=w_2[each_integ_point] wtot=wtot+wtri*abs_det_jac*aux_RNM.dot_product(w_1_this_point,w_2_this_point)/mu_elem aux_RNM.reluctance_matrix_control(face_ID_1,face_ID_2,faces_rel_matrix,wtot,False,faces_list,str_noflux_face) aux_RNM.reluctance_matrix_control(face_ID_1,face_ID_2,faces_rel_spare,wtot,False,faces_list,str_noflux_face) print_message("Integration process - Done") # Connection between the physical line with the circuit node print_message("External faces") magnetic_short_circuit_reluctance=global_variables.magnetic_short_circuit_reluctance for counter,each_face in enumerate(faces_list): if each_face.elem_2==str_noflux_face: for each_face_con in elem_2D_ID: nodes_face_shared=all_elem_nodes_3D[each_face_con] phys_line=elem_tags[each_face_con][0] for each_coupling in coupling: if each_coupling.PhysLine==phys_line: bool_connect=True for each_node_this_face in each_face.nodes_list: if each_node_this_face not in nodes_face_shared: bool_connect=False if bool_connect: # Redefine the face new_face=Face(each_face.nodes_list,each_face.elem_1,each_coupling.Node+number_elements) faces_list[counter]=new_face each_coupling.Face_ID_List.append(counter) #Set the reluctance as a magnetic short circuit # aux_RNM.reluctance_matrix_control(counter,counter,faces_rel_spare,magnetic_short_circuit_reluctance,False) #%% Delete the faces without external connections faces_ID_deleted_list=list() faces_deleted_list=list() counter=0 #Delete from reluctances and fmm matrix for face_counter in xrange(len(faces_list)): if faces_list[face_counter].elem_2==str_noflux_face: faces_ID_deleted_list.append(face_counter) faces_rel_matrix=np.delete(faces_rel_matrix, faces_ID_deleted_list, axis=0) faces_rel_matrix=np.delete(faces_rel_matrix, faces_ID_deleted_list, axis=1) faces_fmm_matrix=np.delete(faces_fmm_matrix, faces_ID_deleted_list, axis=0) ##Delete from faces_list counter=0 for each in faces_ID_deleted_list: face_ID=each+counter this_face=faces_list[face_ID] faces_list.remove(this_face) faces_deleted_list.append(this_face) counter-=1 #%% Add the external circuit reluctances external_nodes_list=list() rows,cols=faces_rel_matrix.shape for each in external_reluctances: mu_elem=vacuum.mu0*materials_lib[each.Material].Permeability #Get the list of external nodes if each.node_from not in external_nodes_list: external_nodes_list.append(each.node_from) if each.node_to not in external_nodes_list: external_nodes_list.append(each.node_to) #add the reluctance in the matrix system row_matrix=np.zeros((1,cols)) faces_rel_matrix=np.vstack((faces_rel_matrix,row_matrix)) rows+=1 col_matrix=np.zeros((rows,1)) faces_rel_matrix=np.hstack((faces_rel_matrix,col_matrix)) cols+=1 faces_fmm_matrix=np.vstack((faces_fmm_matrix,each.fmm)) #reluctance value reluctance_value=each.LS/mu_elem faces_rel_matrix[rows-1,cols-1]=reluctance_value #create a new face in the faces_list new_face=Face([],each.node_from+number_elements,each.node_to+number_elements) faces_list.append(new_face) #Get the list of external nodes for each in coupling: if each.Node not in external_nodes_list: external_nodes_list.append(each.Node ) print_message("External faces - Done") #%% Incidence matrix print_message("Incidence matrix") external_nodes=0 if run_external_circuit: external_nodes+=len(external_nodes_list) else: external_nodes+=0 total_nodes=number_elements+external_nodes incidence_matrix=np.zeros((total_nodes,len(faces_list))) for counter,each_face in enumerate(faces_list): if each_face.elem_2!=str_noflux_face: incidence_matrix[each_face.elem_1,counter]=1 incidence_matrix[each_face.elem_2,counter]=-1 else: incidence_matrix[each_face.elem_1,counter]=1 incidence_matrix[total_nodes-1,counter]=-1 print_message("Incidence matrix - Done") return faces_ID,results_path,faces_rel_matrix,incidence_matrix,faces_fmm_matrix,faces_ID_deleted_list,faces_list,faces_deleted_list
def integration_process(folder_path, preProcData): file_names = File_names() results_folder = file_names.get_results_folder_name() results_path = os.path.join(folder_path, results_folder) # Source field run_surface_integral = False run_biot_savart = True run_VS = False #%% Instances and geral definitions global_variables = GlobalVariables() error = Errors() operations = Operations() materials_lib = get_materials_lib() vacuum = Vacuum() get_gauss_points_class = GaussPoints() shape_functions = ShapeFuncions() operations = Operations() str_noflux_face = global_variables.str_noflux_face results_folder = file_names.get_results_folder_name() face = Face() #------------------------------------------------------------------------------ # Setup regions_material = preProcData.RegionMaterial regions_excitation = preProcData.RegionExcitation boundary = preProcData.BC external_reluctances = preProcData.ExternalReluctances coupling = preProcData.CoupNet #------------------------------------------------------------------------------ # Mesh mesh_data = preProcData.MeshData all_elem_nodes_3D = mesh_data.ElemNodes nodes_coordenates = mesh_data.NodesCoordenates elem_tags = mesh_data.ElemTags elem_type = mesh_data.ElemType #%% Get 2D and 3D elements, with their materials name elem_2D_ID = list() elem_type_3D = list() elem_nodes_3D = list() elem_tags_3D = list() region_ID_list_3D = list() number_elements_2D = 0 for counter, each_elem in enumerate(all_elem_nodes_3D): this_elem_type = elem_type[counter] if this_elem_type < 4: elem_2D_ID.append(counter) number_elements_2D += 1 else: elem_nodes_3D.append(each_elem) elem_type_3D.append(elem_type[counter]) elem_tags_3D.append(elem_tags[counter]) find = False for each_region in regions_material: if each_region.RegionNumber == elem_tags[counter][0]: region_ID_list_3D.append(each_region.MaterialName) find = True if not find: error.physical_surface_not_defined( str(each_region.RegionNumber), elem_tags[counter][0]) number_elements = len(elem_nodes_3D) number_nodes = len(nodes_coordenates) faces_ID = list() faces_list = list() plot_test_coord = list() plot_test_field = list() #%%Get source field field_solution = list() run_permanent_magnets = False # Run Permanent Magnets for each_region in regions_material: for each in materials_lib[each_region.MaterialName].Hc: if each != 0.0: permanent_magnets.run_permanent_magnets( preProcData, folder_path) run_permanent_magnets = True break #Read the fields if run_biot_savart or run_permanent_magnets: results_folder = file_names.get_results_folder_name() folder_name = os.path.join(folder_path, results_folder) #Gauss points IDs this_file_name = file_names.get_Gauss_points_ID_file_name() full_path = os.path.join(folder_name, this_file_name) points_IDs = np.genfromtxt(full_path, delimiter=' ', dtype='int', usecols=(1, 2, 3, 4)) points_ID_elem_all = np.genfromtxt(full_path, delimiter=' ', dtype='int', usecols=(0)) points_ID_elem = points_ID_elem_all - number_elements_2D points_ID_elem = points_ID_elem.tolist() points_ID_elem_all = points_ID_elem_all.tolist() # Gauss points coordinates this_file_name = file_names.get_Gauss_points_coordinates_file_name() full_path = os.path.join(folder_name, this_file_name) coordinates = np.genfromtxt(full_path, delimiter=' ', dtype='double') # Fields this_file_name = file_names.get_Gauss_points_H_field_file_name() # this_file_name="H_source_FFEM.txt" full_path = os.path.join(folder_name, this_file_name) fields = np.genfromtxt(full_path, delimiter=' ', dtype='double') for elem_counter in range(0, number_elements): this_elem_type = elem_type_3D[elem_counter] gauss_points = get_gauss_points_class.get_gauss_points( this_elem_type) number_integ_points = len( get_gauss_points_class.get_gauss_points(this_elem_type)) this_points_field = list() if elem_counter in points_ID_elem: this_elem = points_ID_elem.index(elem_counter) for k in points_IDs[this_elem].tolist(): Hxy = np.zeros((3, 1)) Hxy[0, 0] = fields[k, 0] Hxy[1, 0] = fields[k, 1] Hxy[2, 0] = fields[k, 2] this_points_field.append(Hxy) else: for k in xrange(number_integ_points): Hxy = np.zeros((3, 1)) this_points_field.append(Hxy) field_solution.append(this_points_field) run_external_circuit = False if len(coupling) > 0: run_external_circuit = True #%%Creates the face list print_message("Creating faces list") for elem_counter in range(0, number_elements): number_local_faces = shape_functions.get_number_faces(this_elem_type) this_elem_type = elem_type_3D[elem_counter] this_element_nodes = elem_nodes_3D[elem_counter] faces_nodes_ID = shape_functions.get_nodes_ID_2_face(this_elem_type) number_faces, nodes_per_face = faces_nodes_ID.shape local_faces_ID = list() for local_face_counter in range(0, number_faces): nodes_list = list() for node_counter in range(nodes_per_face): node_ID = faces_nodes_ID[local_face_counter, node_counter] nodes_list.append(this_element_nodes[node_ID]) local_faces_ID.append( face.add_to_list(nodes_list, elem_counter, faces_list)) faces_ID.append(local_faces_ID) print_message("Creating faces list - Done") #%%Integration print_message("Integration process") num_meshed_rel = len(faces_list) num_non_meshed_rel = len(external_reluctances) num_total_rel = num_meshed_rel + num_non_meshed_rel #sparse matrix cols_rel_sparse = list() rows_rel_sparse = list() #reluctance matrix diagonal = list() for each_element_faces in faces_ID: numbre_faces_this_element = len(each_element_faces) for face_counter_1 in xrange(numbre_faces_this_element): pos_1 = each_element_faces[face_counter_1] for face_counter_2 in xrange(numbre_faces_this_element): pos_2 = each_element_faces[face_counter_2] if pos_1 == pos_2: if pos_1 not in diagonal: rows_rel_sparse.append(pos_1) cols_rel_sparse.append(pos_2) diagonal.append(pos_1) else: rows_rel_sparse.append(pos_1) cols_rel_sparse.append(pos_2) data_rel_sparse = np.zeros(len(rows_rel_sparse)) faces_rel_spare = csr_matrix( (data_rel_sparse, (rows_rel_sparse, cols_rel_sparse)), shape=(num_total_rel, num_total_rel)) #fmm matrix cols_fmm_sparse = np.zeros(num_meshed_rel) rows_fmm_sparse = xrange(0, num_meshed_rel) data_fmm_sparse = np.zeros(num_meshed_rel) fmm_sparse = csr_matrix( (data_fmm_sparse, (rows_fmm_sparse, cols_fmm_sparse)), shape=(num_total_rel, 1)) #source_flux matrix cols_source_flux_sparse = np.zeros(num_meshed_rel) rows_source_flux_sparse = xrange(0, num_meshed_rel) data_source_flux_sparse = np.zeros(num_meshed_rel) source_flux_sparse = csr_matrix( (data_source_flux_sparse, (rows_source_flux_sparse, cols_source_flux_sparse)), shape=(num_total_rel, 1)) #grad_phi matrix # cols_grad_phi_sparse=np.zeros(num_meshed_rel) # rows_grad_phi_sparse=xrange(0,num_meshed_rel) # data_grad_phi_sparse=np.zeros(num_meshed_rel) # grad_phi_sparse=csr_matrix((data_grad_phi_sparse, (rows_grad_phi_sparse, cols_grad_phi_sparse)), shape=(num_total_rel,1)) this_elem_type = "" plot_field = list() plot_shape_functions = list() # plot_test_coord=list() BC_nodes = list() BC_values = list() for elem_counter in xrange(number_elements): this_elem_type_changed = elem_type_3D[elem_counter] if this_elem_type != this_elem_type_changed: this_elem_type = this_elem_type_changed gauss_points = get_gauss_points_class.get_gauss_points( this_elem_type) number_local_faces = shape_functions.get_number_faces( this_elem_type) number_integ_points = len( get_gauss_points_class.get_gauss_points(this_elem_type)) wtri = get_gauss_points_class.get_integration_weight( this_elem_type) faces_ID_Elem = faces_ID[elem_counter] this_element_nodes = elem_nodes_3D[elem_counter] mur_r = materials_lib[region_ID_list_3D[elem_counter]].Permeability mu_elem = vacuum.mu0 * mur_r # x=nodes_coordenates[this_element_nodes[0]][1] # Get W at reference element w_local_this_element = list() #[gauss point][face] for each_integ_point in xrange(number_integ_points): #u,v,w coordinates u = gauss_points[each_integ_point, 0] v = gauss_points[each_integ_point, 1] w = gauss_points[each_integ_point, 2] # Shape functions @ reference element w_local_this_point = shape_functions.get_facet_shape_function( this_elem_type, u, v, w) w_local_this_element.append(w_local_this_point) # Shape functions @ real element for each face w_real_all_points = list( ) # w_real_lista[0] contains the shape function of all points for face 0 #Boundary conditions # Hxy=field_solution[elem_counter][each_integ_point] # if Hxy[0,0]!=0 or Hxy[1,0]!=0 or Hxy[2,0]!=0: # BC_nodes.append(elem_counter) # BC_values.append(x) # Face 0...Fn #P0 W #Pn for face_counter in xrange(number_local_faces): w_real_this_point = list() for point_counter in range(0, number_integ_points): w_local = w_local_this_element[point_counter][face_counter] w_real = operations.convert_local_real_Piola( this_elem_type, w_local[0, 0], w_local[0, 1], w_local[0, 2], this_element_nodes, nodes_coordenates) w_real_this_point.append(w_real) w_real_all_points.append(w_real_this_point) # Source fields for local_face_counter in xrange(number_local_faces): w_1 = copy.deepcopy(w_real_all_points[local_face_counter]) face_ID_1 = faces_ID_Elem[local_face_counter] if faces_list[face_ID_1].elem_2 == elem_counter: for each in w_1: each = matrix_aux.invert_w(each) elem_ID_all = elem_counter + number_elements_2D # this_3D_ID=points_ID_elem_all.index(elem_ID_all) # mmf source integration process source = 0 this_face_nodes = faces_list[face_ID_1].nodes_list # # this_elem = points_ID_elem.index(elem_counter) this_gauss_points_ID = points_IDs[this_elem].tolist() Hxy = np.zeros((3, 1)) for each_integ_point in xrange(number_integ_points): if run_biot_savart or run_permanent_magnets: # Hxy=field_solution[elem_counter][each_integ_point] this_point_ID = this_gauss_points_ID[each_integ_point] Hxy[0, 0] = fields[this_point_ID, 0] Hxy[1, 0] = fields[this_point_ID, 1] Hxy[2, 0] = fields[this_point_ID, 2] if Hxy[0, 0] != 0 or Hxy[1, 0] != 0 or Hxy[2, 0] != 0: w_1_this_point = w_1[each_integ_point] #u,v,p coordinates u = gauss_points[each_integ_point, 0] v = gauss_points[each_integ_point, 1] p = gauss_points[each_integ_point, 2] w = w_1_this_point plot_shape_functions.append(w) plot_test_field.append(Hxy) plot_test_coord.append(coordinates[this_point_ID]) # Jacobian jac = operations.get_jacobian(this_elem_type, this_element_nodes, nodes_coordenates, u, v, p) det_jac = np.linalg.det(jac) abs_det_jac = np.abs(det_jac) #Integration source = source + wtri * abs_det_jac * matrix_aux.dot_product( w, Hxy) fmm_sparse[face_ID_1, 0] = fmm_sparse[face_ID_1, 0] + source # Relutances integration process for local_face_counter_2 in xrange(number_local_faces): w_2 = copy.deepcopy(w_real_all_points[local_face_counter_2]) face_ID_2 = faces_ID_Elem[local_face_counter_2] if faces_list[face_ID_2].elem_2 == elem_counter: for each in w_2: each = matrix_aux.invert_w(each) wtot = 0.0 for each_integ_point in range(0, number_integ_points): u = gauss_points[each_integ_point, 0] v = gauss_points[each_integ_point, 1] p = gauss_points[each_integ_point, 2] # Jacobian jac = operations.get_jacobian(this_elem_type, this_element_nodes, nodes_coordenates, u, v, p) det_jac = np.linalg.det(jac) abs_det_jac = np.abs(det_jac) # Reluctance w_1_this_point = w_1[each_integ_point] w_2_this_point = w_2[each_integ_point] wtot = wtot + wtri * abs_det_jac * matrix_aux.dot_product( w_1_this_point, w_2_this_point) / mu_elem faces_rel_spare[face_ID_1, face_ID_2] += wtot print_message("Integration process - Done") #%% Connection between the physical line with the circuit node print_message("External faces") for counter, each_face in enumerate(faces_list): if each_face.elem_2 == str_noflux_face: for each_face_con in elem_2D_ID: nodes_face_shared = all_elem_nodes_3D[each_face_con] phys_line = elem_tags[each_face_con][0] #Coupling with external reluctances for each_coupling in coupling: if each_coupling.PhysLine == phys_line: bool_connect = True for each_node_this_face in each_face.nodes_list: if each_node_this_face not in nodes_face_shared: bool_connect = False if bool_connect: # Redefine the face new_face = Face( each_face.nodes_list, each_face.elem_1, each_coupling.Node + number_elements) faces_list[counter] = new_face each_coupling.Face_ID_List.append(counter) #%% Insert the flux sources # BC_nodes=list() if run_surface_integral: folder_name = os.path.join(folder_path, results_folder) full_path = os.path.join(folder_name, "flux_surface.txt") flux_data = np.genfromtxt(full_path, delimiter=' ', dtype='double') flux_source = flux_data[:, 1] flux_source_elem_ID = flux_data[:, 0] num_faces_surface_integral = len(flux_source_elem_ID) external_node_surface_ID_counter = 0 for face_counter in xrange(num_faces_surface_integral): this_elem_face_ID = int(flux_source_elem_ID[face_counter]) this_face_nodes_elem = set(all_elem_nodes_3D[this_elem_face_ID]) for counter, each_face in enumerate(faces_list): this_face_nodes = set(each_face.nodes_list) if this_face_nodes_elem.issubset(this_face_nodes): # print this_elem_face_ID # external_node_surface_ID=len(coupling)+number_elements-1 # BC_nodes.append(external_node_surface_ID) # external_node_surface_ID_counter+=1 new_face = Face(each_face.nodes_list, each_face.elem_1, each_face.elem_2) faces_list[counter] = new_face source_flux_sparse[counter] = flux_source[face_counter] faces_rel_spare[counter, counter] = 10000000000000000.0 fmm_sparse[counter, 0] = 0.0 # print each_face.elem_1 # break # BC_values=[0]*len(BC_nodes) #%% Delete the faces without external connections faces_ID_deleted_list = list() faces_deleted_list = list() #Delete from reluctances and fmm matrix counter = 0 for face_counter in xrange(len(faces_list)): if faces_list[face_counter].elem_2 == str_noflux_face: faces_ID_deleted_list.append(face_counter) faces_rel_spare = matrix_aux.delete_sparse_mask(faces_rel_spare, faces_ID_deleted_list, 0) faces_rel_spare = matrix_aux.delete_sparse_mask(faces_rel_spare, faces_ID_deleted_list, 1) fmm_sparse = matrix_aux.delete_sparse_mask(fmm_sparse, faces_ID_deleted_list, 0) source_flux_sparse = matrix_aux.delete_sparse_mask(source_flux_sparse, faces_ID_deleted_list, 0) ##Delete from faces_list counter = 0 for each in faces_ID_deleted_list: face_ID = each + counter this_face = faces_list[face_ID] faces_list.remove(this_face) faces_deleted_list.append(this_face) counter -= 1 #%% Add the external circuit reluctances number_deleted = len(faces_deleted_list) for counter in xrange(num_non_meshed_rel): #reluctance value material = external_reluctances[counter].Material mur = materials_lib[material].Permeability LS = external_reluctances[counter].LS mu_elem = vacuum.mu0 * mur reluctance_value = LS / mu_elem this_position = num_meshed_rel - number_deleted + counter faces_rel_spare[this_position, this_position] = reluctance_value fmm_sparse[this_position] = external_reluctances[counter].fmm source_flux_sparse[this_position] = external_reluctances[counter].flux external_nodes_list = list() for each in external_reluctances: #Get the list of external nodes if each.node_from not in external_nodes_list: external_nodes_list.append(each.node_from) if each.node_to not in external_nodes_list: external_nodes_list.append(each.node_to) #create a new face in the faces_list new_face = Face([], each.node_from + number_elements, each.node_to + number_elements) faces_list.append(new_face) #Get the list of external nodes for each in coupling: if each.Node not in external_nodes_list: external_nodes_list.append(each.Node) print_message("External faces - Done") #%% Incidence matrix print_message("Incidence matrix") external_nodes = 0 if run_external_circuit: external_nodes += len(external_nodes_list) # elif run_surface_integral: # external_nodes+=len(BC_nodes) else: external_nodes += 0 number_faces_list = len(faces_list) total_nodes = number_elements + external_nodes rows_incidence_sparse = list() cols_incidence_sparse = list() data_incidence_sparse = list() for counter in xrange(number_faces_list): this_face = faces_list[counter] rows_incidence_sparse.append(this_face.elem_1) cols_incidence_sparse.append(counter) data_incidence_sparse.append(1.0) rows_incidence_sparse.append(this_face.elem_2) cols_incidence_sparse.append(counter) data_incidence_sparse.append(-1.0) incidence_matrix_sparse = csr_matrix( (data_incidence_sparse, (rows_incidence_sparse, cols_incidence_sparse)), shape=(total_nodes, number_faces_list)) print_message("Incidence matrix - Done") #%%Plot test fields Gmsh_file_name = "test_H_field.txt" path = os.path.join(results_path, Gmsh_file_name) Create_Vector_field(plot_test_coord, plot_test_field, path, "H test") Gmsh_file_name = "test_W.txt" path = os.path.join(results_path, Gmsh_file_name) Create_Vector_field(plot_test_coord, plot_shape_functions, path, "Shape function") print_message("Saving matrices") np.save(os.path.join(results_path, "faces_rel_spare_algo"), faces_rel_spare.toarray()) np.save(os.path.join(results_path, "fmm_sparse_algol"), fmm_sparse.toarray()) np.save(os.path.join(results_path, "incidence_matrix_algo"), incidence_matrix_sparse.toarray()) print_message("Saving matrices: Done") return faces_rel_spare, incidence_matrix_sparse, fmm_sparse, source_flux_sparse, faces_ID, results_path, faces_ID_deleted_list, faces_list, faces_deleted_list, BC_nodes, BC_values
def SolveMagneticCircuit(Ac,Yb, F,J,BC_nodes,BC_values): print_message("Running circuit solver") flux=__solve_nodal_circuit(Ac,Yb, F,J,BC_nodes,BC_values) # flux=solve_nodal_circuit_diagonal(Ac,Yb, F) print_message("Running circuit solver - Done") return flux
def integration_process(folder_path,preProcData): file_names=File_names() results_folder=file_names.get_results_folder_name() results_path=os.path.join(folder_path,results_folder) # Source field mu0=4.0*math.pi*math.pow(10.0,-7.0) run_surface_integral=True run_biot_savart=True run_VS=False perf_mag_surf=177 one_layer_ID=175 #%% Instances and geral definitions global_variables=GlobalVariables() error=Errors() operations=Operations() materials_lib=get_materials_lib() vacuum=Vacuum() get_gauss_points_class=GaussPoints() shape_functions=ShapeFuncions() operations=Operations() str_noflux_face=global_variables.str_noflux_face results_folder=file_names.get_results_folder_name() face=Face() #------------------------------------------------------------------------------ # Setup regions_material=preProcData.RegionMaterial regions_excitation=preProcData.RegionExcitation boundary=preProcData.BC external_reluctances=preProcData.ExternalReluctances coupling=preProcData.CoupNet #------------------------------------------------------------------------------ # Mesh mesh_data=preProcData.MeshData all_elem_nodes_3D= mesh_data.ElemNodes nodes_coordenates=mesh_data.NodesCoordenates elem_tags=mesh_data.ElemTags elem_type=mesh_data.ElemType #%% Get 2D and 3D elements, with their materials name elem_2D_ID=list() elem_type_3D=list() elem_nodes_3D=list() elem_tags_3D=list() region_ID_list_3D=list() number_elements_2D=0 nodes_phys_surf=list() for counter,each_elem in enumerate(all_elem_nodes_3D): this_elem_type=elem_type[counter] if this_elem_type<4: elem_2D_ID.append(counter) number_elements_2D+=1 if elem_tags[counter][0]==perf_mag_surf: for each in all_elem_nodes_3D[counter]: if each not in nodes_phys_surf: nodes_phys_surf.append(each) else: elem_nodes_3D.append(each_elem) elem_type_3D.append(elem_type[counter]) elem_tags_3D.append(elem_tags[counter]) find=False for each_region in regions_material: if each_region.RegionNumber==elem_tags[counter][0]: region_ID_list_3D.append(each_region.MaterialName) find=True if not find: error.physical_surface_not_defined(str(each_region.RegionNumber),elem_tags[counter][0]) number_elements=len(elem_nodes_3D) #only 3D elements number_nodes=len(nodes_coordenates) faces_ID=list() faces_list=list() # nodes_phys_surf=set(nodes_phys_surf) plot_field=list() plot_shape_functions=list() plot_test_coord=list() #%%Get source field field_solution=list() run_permanent_magnets=False # Run Permanent Magnets for each_region in regions_material: for each in materials_lib[each_region.MaterialName].Hc: if each !=0.0: permanent_magnets.run_permanent_magnets(preProcData,folder_path) run_permanent_magnets=True break #Read the fields if run_biot_savart or run_permanent_magnets: results_folder=file_names.get_results_folder_name() folder_name=os.path.join(folder_path,results_folder) #Gauss points IDs this_file_name=file_names.get_Gauss_points_ID_file_name() full_path=os.path.join(folder_name,this_file_name) points_IDs = np.genfromtxt(full_path,delimiter=' ',dtype='int', usecols=(1,2,3,4)) points_ID_elem_all = np.genfromtxt(full_path,delimiter=' ',dtype='int', usecols=(0)) points_ID_elem=points_ID_elem_all-number_elements_2D points_ID_elem=points_ID_elem.tolist() points_ID_elem_all=points_ID_elem_all.tolist() # Gauss points coordinates this_file_name=file_names.get_Gauss_points_coordinates_file_name() full_path=os.path.join(folder_name,this_file_name) coordinates = np.genfromtxt(full_path,delimiter=' ',dtype='double') # Fields this_file_name=file_names.get_Gauss_points_H_field_file_name() # this_file_name="H_source_FFEM.txt" full_path=os.path.join(folder_name,this_file_name) fields = np.genfromtxt(full_path,delimiter=' ',dtype='double') for elem_counter in range(0,number_elements): this_elem_type=elem_type_3D[elem_counter] gauss_points=get_gauss_points_class.get_gauss_points(this_elem_type) number_integ_points=len(get_gauss_points_class.get_gauss_points(this_elem_type)) this_points_field=list() if elem_counter in points_ID_elem: this_elem=points_ID_elem.index(elem_counter) for k in points_IDs[this_elem].tolist(): Hxy=np.zeros((3,1)) Hxy[0,0]=fields[k,0] Hxy[1,0]=fields[k,1] Hxy[2,0]=fields[k,2] this_points_field.append(Hxy) else: for k in xrange(number_integ_points): Hxy=np.zeros((3,1)) this_points_field.append(Hxy) field_solution.append(this_points_field) run_external_circuit=False if len(coupling)>0: run_external_circuit=True #%%Creates the face list print_message("Creating faces list") for elem_counter in range(0,number_elements): number_local_faces=shape_functions.get_number_faces(this_elem_type) this_elem_type=elem_type_3D[elem_counter] this_element_nodes=elem_nodes_3D[elem_counter] faces_nodes_ID=shape_functions.get_nodes_ID_2_face(this_elem_type) number_faces,nodes_per_face=faces_nodes_ID.shape local_faces_ID=list() for local_face_counter in range(0,number_faces): nodes_list=list() for node_counter in range(nodes_per_face): node_ID=faces_nodes_ID[local_face_counter,node_counter] nodes_list.append(this_element_nodes[node_ID]) local_faces_ID.append(face.add_to_list(nodes_list,elem_counter,faces_list)) faces_ID.append(local_faces_ID) print_message("Creating faces list - Done") #%%Integration print_message("Integration process") num_meshed_rel=len(faces_list) num_non_meshed_rel=len(external_reluctances) num_total_rel=num_meshed_rel+num_non_meshed_rel #sparse matrix cols_rel_sparse=list() rows_rel_sparse=list() counter_elem_suf=0 #reluctance matrix diagonal=list() for each_element_faces in faces_ID: numbre_faces_this_element=len(each_element_faces) for face_counter_1 in xrange(numbre_faces_this_element): pos_1=each_element_faces[face_counter_1] for face_counter_2 in xrange(numbre_faces_this_element): pos_2=each_element_faces[face_counter_2] if pos_1==pos_2: if pos_1 not in diagonal: rows_rel_sparse.append(pos_1) cols_rel_sparse.append(pos_2) diagonal.append(pos_1) else: rows_rel_sparse.append(pos_1) cols_rel_sparse.append(pos_2) data_rel_sparse=np.zeros(len(rows_rel_sparse)) faces_rel_spare=csr_matrix((data_rel_sparse, (rows_rel_sparse, cols_rel_sparse)), shape=(num_total_rel, num_total_rel)) #fmm matrix cols_fmm_sparse=np.zeros(num_meshed_rel) rows_fmm_sparse=xrange(0,num_meshed_rel) data_fmm_sparse=np.zeros(num_meshed_rel) fmm_sparse=csr_matrix((data_fmm_sparse, (rows_fmm_sparse, cols_fmm_sparse)), shape=(num_total_rel,1)) #source_flux matrix cols_source_flux_sparse=np.zeros(num_meshed_rel) rows_source_flux_sparse=xrange(0,num_meshed_rel) data_source_flux_sparse=np.zeros(num_meshed_rel) source_flux_sparse=csr_matrix((data_source_flux_sparse, (rows_source_flux_sparse, cols_source_flux_sparse)), shape=(num_total_rel,1)) #grad_phi matrix # cols_grad_phi_sparse=np.zeros(num_meshed_rel) # rows_grad_phi_sparse=xrange(0,num_meshed_rel) # data_grad_phi_sparse=np.zeros(num_meshed_rel) # grad_phi_sparse=csr_matrix((data_grad_phi_sparse, (rows_grad_phi_sparse, cols_grad_phi_sparse)), shape=(num_total_rel,1)) this_elem_type="" for elem_counter in xrange(number_elements): this_elem_type_changed=elem_type_3D[elem_counter] if this_elem_type!=this_elem_type_changed: this_elem_type=this_elem_type_changed gauss_points=get_gauss_points_class.get_gauss_points(this_elem_type) number_local_faces=shape_functions.get_number_faces(this_elem_type) number_integ_points=len(get_gauss_points_class.get_gauss_points(this_elem_type)) wtri=get_gauss_points_class.get_integration_weight(this_elem_type) faces_ID_Elem=faces_ID[elem_counter] this_element_nodes=elem_nodes_3D[elem_counter] mur_r=materials_lib[region_ID_list_3D[elem_counter]].Permeability mu_elem=vacuum.mu0*mur_r k_sf=1.0 if run_VS: if mur_r>1.0: k_sf=-1.0*mu0*((1.0/mu_elem)-(1.0/mu0)) else: k_sf=0 # Get W at reference element w_local_this_element=list() #[gauss point][face] for each_integ_point in xrange(number_integ_points): #u,v,w coordinates u=gauss_points[each_integ_point,0] v=gauss_points[each_integ_point,1] w=gauss_points[each_integ_point,2] # Shape functions @ reference element w_local_this_point=shape_functions.get_facet_shape_function(this_elem_type,u,v,w) w_local_this_element.append(w_local_this_point) # Shape functions @ real element for each face w_real_all_points=list() # w_real_lista[0] contains the shape function of all points for face 0 # Face 0...Fn #P0 W #Pn for face_counter in xrange(number_local_faces): w_real_this_point=list() for point_counter in range(0,number_integ_points): w_local=w_local_this_element[point_counter][face_counter] w_real=operations.convert_local_real_Piola(this_elem_type,w_local[0,0],w_local[0,1],w_local[0,2],this_element_nodes,nodes_coordenates) w_real_this_point.append(w_real) w_real_all_points.append(w_real_this_point) # Source fields elem_ID_all=elem_counter+number_elements_2D for local_face_counter in xrange(number_local_faces): w_1=copy.deepcopy(w_real_all_points[local_face_counter]) face_ID_1=faces_ID_Elem[local_face_counter] if faces_list[face_ID_1].elem_2==elem_counter: for each in w_1: each=matrix_aux.invert_w(each) # mmf source integration process # if (52 in faces_list[face_ID_1].nodes_list) and (118 in faces_list[face_ID_1].nodes_list) and (384 in faces_list[face_ID_1].nodes_list): # faces_list[face_ID_1].print_face() # run_this_face=True counter_nodes=0 for each in faces_list[face_ID_1].nodes_list: if each in nodes_phys_surf: counter_nodes=counter_nodes+1 # run_this_face=False run_this_face=False if elem_counter in points_ID_elem: run_this_face=True # if (50 in faces_list[face_ID_1].nodes_list) and (120 in faces_list[face_ID_1].nodes_list): # run_this_face=True # faces_list[face_ID_1].print_face() ## print(faces_list[face_ID_1].nodes_list) if run_this_face: #Gets the ID of the element this_3D_ID=points_ID_elem_all.index(elem_ID_all) # print(this_3D_ID) this_face_nodes=faces_list[face_ID_1].nodes_list # faces_list[face_ID_1].print_face() source=0 for each_integ_point in xrange(number_integ_points): # this_Gauss_point_ID=points_IDs[this_3D_ID][each_integ_point] # if run_biot_savart or run_permanent_magnets: Hxy=np.zeros((3,1)) this_gauss_point_ID=points_IDs[this_3D_ID][each_integ_point] Hxy[0,0]=fields[this_gauss_point_ID][0] Hxy[1,0]=fields[this_gauss_point_ID][1] Hxy[2,0]=fields[this_gauss_point_ID][2] # Hxy=field_solution[elem_counter][each_integ_point]*k_sf w_1_this_point=w_1[each_integ_point] #u,v,p coordinates u=gauss_points[each_integ_point,0] v=gauss_points[each_integ_point,1] p=gauss_points[each_integ_point,2] w=w_1_this_point # Normal vector node1=this_face_nodes[0] node2=this_face_nodes[1] node3=this_face_nodes[2] P_1=np.array([nodes_coordenates[node1][0],nodes_coordenates[node1][1],nodes_coordenates[node1][2]]) P_2=np.array([nodes_coordenates[node2][0],nodes_coordenates[node2][1],nodes_coordenates[node2][2]]) P_3=np.array([nodes_coordenates[node3][0],nodes_coordenates[node3][1],nodes_coordenates[node3][2]]) A=P_2-P_1 B=P_3-P_1 AxB=np.cross(A,B) nor=linalg.norm(AxB) n=AxB/nor n=np.array([[n[0]],[n[1]],[n[2]]]) #Shape funtions vdotn=matrix_aux.dot_product(w,n) w_n=n*vdotn w_t=w-w_n w=-w_n plot_shape_functions.append(w) plot_test_coord.append(coordinates[this_gauss_point_ID]) #Source field vdotn=matrix_aux.dot_product(Hxy,n) Hxy_n=n*vdotn plot_field.append(Hxy) # Jacobian jac=operations.get_jacobian(this_elem_type,this_element_nodes,nodes_coordenates,u,v,p) det_jac=np.linalg.det(jac) abs_det_jac=np.abs(det_jac) #Integration source=source+wtri*abs_det_jac*matrix_aux.dot_product(w,Hxy) fmm_sparse[face_ID_1,0]=fmm_sparse[face_ID_1,0]+source # Relutances integration process for local_face_counter_2 in xrange(number_local_faces): w_2=copy.deepcopy(w_real_all_points[local_face_counter_2]) face_ID_2=faces_ID_Elem[local_face_counter_2] if faces_list[face_ID_2].elem_2==elem_counter: for each in w_2: each=matrix_aux.invert_w(each) wtot=0.0 for each_integ_point in range(0,number_integ_points): u=gauss_points[each_integ_point,0] v=gauss_points[each_integ_point,1] p=gauss_points[each_integ_point,2] # Jacobian jac=operations.get_jacobian(this_elem_type,this_element_nodes,nodes_coordenates,u,v,p) det_jac=np.linalg.det(jac) abs_det_jac=np.abs(det_jac) # Reluctance w_1_this_point=w_1[each_integ_point] w_2_this_point=w_2[each_integ_point] wtot=wtot+wtri*abs_det_jac*matrix_aux.dot_product(w_1_this_point,w_2_this_point)/mu_elem faces_rel_spare[face_ID_1,face_ID_2]+=wtot print_message("Integration process - Done") #%% Connection between the physical line with the circuit node print_message("External faces") for counter,each_face in enumerate(faces_list): if each_face.elem_2==str_noflux_face: for each_face_con in elem_2D_ID: nodes_face_shared=all_elem_nodes_3D[each_face_con] phys_line=elem_tags[each_face_con][0] #Coupling with external reluctances for each_coupling in coupling: if each_coupling.PhysLine==phys_line: bool_connect=True for each_node_this_face in each_face.nodes_list: if each_node_this_face not in nodes_face_shared: bool_connect=False if bool_connect: # Redefine the face new_face=Face(each_face.nodes_list,each_face.elem_1,each_coupling.Node+number_elements) faces_list[counter]=new_face each_coupling.Face_ID_List.append(counter) #%% Insert the flux sources BC_nodes=list() if run_surface_integral: folder_name=os.path.join(folder_path,results_folder) full_path=os.path.join(folder_name,"flux_surface.txt") flux_data = np.genfromtxt(full_path,delimiter=' ',dtype='double') flux_source =flux_data[:,1] flux_source_elem_ID=flux_data[:,0] num_faces_surface_integral=len(flux_source_elem_ID) # external_node_surface_ID_counter=0 for face_counter in xrange(num_faces_surface_integral): this_elem_face_ID=int(flux_source_elem_ID[face_counter]) this_face_nodes_elem=set(all_elem_nodes_3D[this_elem_face_ID]) for counter,each_face in enumerate(faces_list): this_face_nodes=set(each_face.nodes_list) if this_face_nodes_elem.issubset(this_face_nodes): # print this_elem_face_ID # external_node_surface_ID=len(coupling)+number_elements-1 # BC_nodes.append(external_node_surface_ID) # external_node_surface_ID_counter+=1 new_face=Face(each_face.nodes_list,each_face.elem_1,each_face.elem_2) faces_list[counter]=new_face source_flux_sparse[counter]=flux_source[face_counter] faces_rel_spare[counter,counter]=10000000000000000.0 fmm_sparse[counter,0]=0.0 # print each_face.elem_1 # break BC_values=[0]*len(BC_nodes) #%% Delete the faces without external connections faces_ID_deleted_list=list() faces_deleted_list=list() #Delete from reluctances and fmm matrix counter=0 for face_counter in xrange(len(faces_list)): if faces_list[face_counter].elem_2==str_noflux_face: faces_ID_deleted_list.append(face_counter) faces_rel_spare=matrix_aux.delete_sparse_mask(faces_rel_spare,faces_ID_deleted_list,0) faces_rel_spare=matrix_aux.delete_sparse_mask(faces_rel_spare,faces_ID_deleted_list,1) fmm_sparse=matrix_aux.delete_sparse_mask(fmm_sparse,faces_ID_deleted_list,0) source_flux_sparse=matrix_aux.delete_sparse_mask(source_flux_sparse,faces_ID_deleted_list,0) ##Delete from faces_list counter=0 for each in faces_ID_deleted_list: face_ID=each+counter this_face=faces_list[face_ID] faces_list.remove(this_face) faces_deleted_list.append(this_face) counter-=1 #%% Add the external circuit reluctances number_deleted=len(faces_deleted_list) for counter in xrange(num_non_meshed_rel): #reluctance value material=external_reluctances[counter].Material mur=materials_lib[material].Permeability LS=external_reluctances[counter].LS mu_elem=vacuum.mu0*mur reluctance_value=LS/mu_elem this_position=num_meshed_rel-number_deleted+counter faces_rel_spare[this_position,this_position]=reluctance_value fmm_sparse[this_position]=external_reluctances[counter].fmm source_flux_sparse[this_position]=external_reluctances[counter].flux external_nodes_list=list() for each in external_reluctances: #Get the list of external nodes if each.node_from not in external_nodes_list: external_nodes_list.append(each.node_from) if each.node_to not in external_nodes_list: external_nodes_list.append(each.node_to) #create a new face in the faces_list new_face=Face([],each.node_from+number_elements,each.node_to+number_elements) faces_list.append(new_face) #Get the list of external nodes for each in coupling: if each.Node not in external_nodes_list: external_nodes_list.append(each.Node ) print_message("External faces - Done") #%% Incidence matrix print_message("Incidence matrix") external_nodes=0 if run_external_circuit: external_nodes+=len(external_nodes_list) # elif run_surface_integral: # external_nodes+=len(BC_nodes) else: external_nodes+=0 number_faces_list=len(faces_list) total_nodes=number_elements+external_nodes rows_incidence_sparse=list() cols_incidence_sparse=list() data_incidence_sparse=list() for counter in xrange(number_faces_list): this_face=faces_list[counter] rows_incidence_sparse.append(this_face.elem_1) cols_incidence_sparse.append(counter) data_incidence_sparse.append(1.0) rows_incidence_sparse.append(this_face.elem_2) cols_incidence_sparse.append(counter) data_incidence_sparse.append(-1.0) incidence_matrix_sparse=csr_matrix((data_incidence_sparse, (rows_incidence_sparse, cols_incidence_sparse)), shape=(total_nodes,number_faces_list)) print_message("Incidence matrix - Done") #%%Plot test fields Gmsh_file_name="test_H_field.txt" path=os.path.join(results_path,Gmsh_file_name) Create_Vector_field(plot_test_coord,plot_field,path,"H test") Gmsh_file_name="test_W.txt" path=os.path.join(results_path,Gmsh_file_name) Create_Vector_field(plot_test_coord,plot_shape_functions,path,"Shape function") return faces_rel_spare,incidence_matrix_sparse,fmm_sparse,source_flux_sparse,faces_ID,results_path,faces_ID_deleted_list,faces_list,faces_deleted_list,BC_nodes,BC_values
def SolveMagneticCircuit(Ac,Yb, F): print_message("Running circuit solver") flux=__solve_nodal_circuit_sparse(Ac,Yb, F) # flux=solve_nodal_circuit_diagonal(Ac,Yb, F) print_message("Running circuit solver - Done") return flux
def read_numeric_file_numpy(file_name): (path_file_local, path_name_local) = os.path.split(file_name) print_message('Reading file: ' + str(path_name_local)) return np.loadtxt(file_name) print_message('Reading file: ' + str(path_name_local) + " - Done!")
def read_numeric_file_numpy(file_name): (path_file_local,path_name_local)=os.path.split(file_name) print_message('Reading file: '+str(path_name_local)) return np.loadtxt(file_name) print_message('Reading file: '+str(path_name_local)+" - Done!")