def main(id_problem, tol=1e-5, N_pts=1000, if_export=False): folder_export = 'example_2_2_tpfa/' + str(id_problem) + "/" file_export = 'tpfa' gb = example_2_2_create_grid.create(id_problem, tol=tol) # Assign parameters example_2_2_data.add_data(gb, tol) # Choose and define the solvers and coupler solver_flux = tpfa.TpfaDFN(gb.dim_max(), 'flow') A_flux, b_flux = solver_flux.matrix_rhs(gb) solver_source = source.IntegralDFN(gb.dim_max(), 'flow') A_source, b_source = solver_source.matrix_rhs(gb) p = sps.linalg.spsolve(A_flux + A_source, b_flux + b_source) solver_flux.split(gb, 'pressure', p) if if_export: save = Exporter(gb, file_export, folder_export) save.write_vtk(['pressure']) b_box = gb.bounding_box() y_range = np.linspace(b_box[0][1] + tol, b_box[1][1] - tol, N_pts) pts = np.stack((1.5 * np.ones(N_pts), y_range, 0.5 * np.ones(N_pts))) values = example_2_2_data.plot_over_line(gb, pts, 'pressure', tol) arc_length = y_range - b_box[0][1] np.savetxt(folder_export + "plot_over_line.txt", (arc_length, values)) # compute the flow rate fvutils.compute_discharges(gb, 'flow') diam, flow_rate = example_2_2_data.compute_flow_rate(gb, tol) np.savetxt(folder_export + "flow_rate.txt", (diam, flow_rate))
def main(id_problem, is_coarse=False, tol=1e-5, N_pts=1000, if_export=False): folder_export = 'example_2_2_vem/' + str(id_problem) + "/" file_export = 'vem' gb = example_2_2_create_grid.create(id_problem, is_coarse=is_coarse, tol=tol) internal_flag = FaceTag.FRACTURE [g.remove_face_tag_if_tag(FaceTag.BOUNDARY, internal_flag) for g, _ in gb] # Assign parameters example_2_2_data.add_data(gb, tol) # Choose and define the solvers and coupler solver_flow = vem_dual.DualVEMDFN(gb.dim_max(), 'flow') A_flow, b_flow = solver_flow.matrix_rhs(gb) solver_source = vem_source.IntegralDFN(gb.dim_max(), 'flow') A_source, b_source = solver_source.matrix_rhs(gb) up = sps.linalg.spsolve(A_flow + A_source, b_flow + b_source) solver_flow.split(gb, "up", up) gb.add_node_props(["discharge", 'pressure', "P0u"]) solver_flow.extract_u(gb, "up", "discharge") solver_flow.extract_p(gb, "up", 'pressure') solver_flow.project_u(gb, "discharge", "P0u") if if_export: save = Exporter(gb, file_export, folder_export) save.write_vtk(['pressure', "P0u"]) b_box = gb.bounding_box() y_range = np.linspace(b_box[0][1] + tol, b_box[1][1] - tol, N_pts) pts = np.stack((1.5 * np.ones(N_pts), y_range, 0.5 * np.ones(N_pts))) values = example_2_2_data.plot_over_line(gb, pts, 'pressure', tol) arc_length = y_range - b_box[0][1] np.savetxt(folder_export + "plot_over_line.txt", (arc_length, values)) # compute the flow rate diam, flow_rate = example_2_2_data.compute_flow_rate_vem(gb, tol) np.savetxt(folder_export + "flow_rate.txt", (diam, flow_rate))