DPF Mechanical 2026 R1

Ans.DataProcessing.operators.result Namespace

Last update: 18.06.2026

Classes

Class Description
acceleration acceleration()
acceleration_X acceleration_X()
acceleration_Y acceleration_Y()
acceleration_Z acceleration_Z()
accu_eqv_creep_strain accu_eqv_creep_strain()
[accu_eqv_plastic_sresult_accu_eqv_plastic_strain.md) accu_eqv_plastic_strain()
[acoustic_energy_denesult_acoustic_energy_density.md) acoustic_energy_density()
[add_rigid_body_motion]_add_rigid_body_motion.md) Adds a given rigid translation, center and rotation from a displacement field. The rotation is given in terms of rotations angles. Note that the displacement field has to be in the global coordinate system ///available inputs: displacement_field (Field), translation_field (Field), rotation_field (Field), center_field (Field), mesh (MeshedRegion) (optional)
[add_rigid_body_motioesult_add_rigid_body_motion_fc.md) Adds a given rigid translation, center and rotation from a displacement field. The rotation is given in terms of rotations angles. Note that the displacement field has to be in the global coordinate system ///available inputs: fields_container (FieldsContainer), translation_field (Field), rotation_field (Field), center_field (Field), mesh (MeshedRegion) (optional)
[artificial_hourglasss_result_artificial_hourglass_energy.md) artificial_hourglass_energy()
beam_axial_force beam_axial_force()
[beam_axial_plastic_strault_beam_axial_plastic_strain.md) beam_axial_plastic_strain()
[beam_axial__result_beam_axial_stress.md) beam_axial_stress()
beam_axial_total_strain beam_axial_total_strain()
[beam_rs_shear_streult_beam_rs_shear_stress.md) beam_rs_shear_stress()
[beam_s_bending_momsult_beam_s_bending_moment.md) beam_s_bending_moment()
[beam_s_shear_force]_beam_s_shear_force.md) beam_s_shear_force()
[beam_t_bending_momsult_beam_t_bending_moment.md) beam_t_bending_moment()
[beam_t_shear_forcet_beam_t_shear_force.md) beam_t_shear_force()
[beam_torsional_moment]_beam_torsional_moment.md) beam_torsional_moment()
beam_tr_shear_stress beam_tr_shear_stress()
cms_dst_table_provider Read CST table from a subfile. ///available inputs: data_sources (DataSources)
cms_matrices_provider Read reduced matrices for cms elements. Extract stiffness, damping, mass matrices and load vector from a subfile. ///available inputs: data_sources (DataSources), matrix_form (bool)
[cms_subfile_info_providert_cms_subfile_info_provider.md) Read required information from a subfile. ///available inputs: data_sources (DataSources), cms_subfile_data (bool), output_maxdof_on_masternodes (bool) (optional)
[co_energy](Ans_DataProcessing_operat()
[compute_invariant_termrs_result_compute_invariant_terms_motion.md) compute_invariant_terms_motion()
[compute_invariant_ors_result_compute_invariant_terms_rbd.md) compute_invariant_terms_rbd()
compute_stress Computes the stress from an elastic strain field. compute_total_strain limitations are applicable for stress computation ///available inputs: scoping (Scoping) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources) (optional), requested_location (string) (optional), strain (FieldsContainer, Field)
compute_stress_1 Computes the stress from an elastic strain field. compute_total_strain limitations are applicable for stress computation Get the 1st principal component. ///available inputs: scoping (Scoping) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources) (optional), requested_location (string) (optional), strain (FieldsContainer, Field)
[compute_stressult_compute_stress_2.md) Computes the stress from an elastic strain field. compute_total_strain limitations are applicable for stress computation Get the 2nd principal component. ///available inputs: scoping (Scoping) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources) (optional), requested_location (string) (optional), strain (FieldsContainer, Field)
[compute_stress_3t_compute_stress_3.md) Computes the stress from an elastic strain field. compute_total_strain limitations are applicable for stress computation Get the 3rd principal component. ///available inputs: scoping (Scoping) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources) (optional), requested_location (string) (optional), strain (FieldsContainer, Field)
[compute_stress_X]_compute_stress_X.md) Computes the stress from an elastic strain field. compute_total_strain limitations are applicable for stress computation Get the XX normal component (00 component). ///available inputs: scoping (Scoping) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources) (optional), requested_location (string) (optional), strain (FieldsContainer, Field)
[compute_stress_XYt_compute_stress_XY.md) Computes the stress from an elastic strain field. compute_total_strain limitations are applicable for stress computation Get the XY shear component (01 component). ///available inputs: scoping (Scoping) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources) (optional), requested_location (string) (optional), strain (FieldsContainer, Field)
compute_stress_XZ Computes the stress from an elastic strain field. compute_total_strain limitations are applicable for stress computation Get the XZ shear component (02 component). ///available inputs: scoping (Scoping) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources) (optional), requested_location (string) (optional), strain (FieldsContainer, Field)
compute_stress_Y Computes the stress from an elastic strain field. compute_total_strain limitations are applicable for stress computation Get the YY normal component (11 component). ///available inputs: scoping (Scoping) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources) (optional), requested_location (string) (optional), strain (FieldsContainer, Field)
compute_stress_YZ Computes the stress from an elastic strain field. compute_total_strain limitations are applicable for stress computation Get the YZ shear component (12 component). ///available inputs: scoping (Scoping) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources) (optional), requested_location (string) (optional), strain (FieldsContainer, Field)
compute_stress_Z Computes the stress from an elastic strain field. compute_total_strain limitations are applicable for stress computation Get the ZZ normal component (22 component). ///available inputs: scoping (Scoping) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources) (optional), requested_location (string) (optional), strain (FieldsContainer, Field)
compute_stress_von_mises Computes the stress from an elastic strain field. compute_total_strain limitations are applicable for stress computationGet the Von Mises equivalent stress. ///available inputs: scoping (Scoping) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources) (optional), requested_location (string) (optional), strain (FieldsContainer, Field)
[compute_total_strault_compute_total_strain.md) compute_total_strain()
[compute_total_rs_result_compute_total_strain_1.md) compute_total_strain_1()
[compute_total_st_result_compute_total_strain_2.md) compute_total_strain_2()
[compute_total_strain_3t_compute_total_strain_3.md) compute_total_strain_3()
[compute_total_st_result_compute_total_strain_X.md) compute_total_strain_X()
[compute_total_straiesult_compute_total_strain_XY.md) compute_total_strain_XY()
[compute_total_straresult_compute_total_strain_XZ.md) compute_total_strain_XZ()
[compute_total_straesult_compute_total_strain_Y.md) compute_total_strain_Y()
[compute_total_strainsult_compute_total_strain_YZ.md) compute_total_strain_YZ()
compute_total_strain_Z compute_total_strain_Z()
[contact_fluid_penetration_pr_result_contact_fluid_penetration_pressure.md) contact_fluid_penetration_pressure()
contact_friction_stress contact_friction_stress()
[contact_gap_distanult_contact_gap_distance.md) contact_gap_distance()
[contact_penetratiolt_contact_penetration.md) contact_penetration()
contact_pressure contact_pressure()
[contact_sliding_distance]_contact_sliding_distance.md) contact_sliding_distance()
contact_status contact_status()
[contact_surface_heat_fsult_contact_surface_heat_flux.md) contact_surface_heat_flux()
contact_total_stress contact_total_stress()
coordinate_system Extracts the Rotation Matrix and Origin of a specific coordinate system. ///available inputs: cs_id (Int32), streams_container (StreamsContainer) (optional), data_sources (DataSources)
coordinates coordinates()
[creep_strault_creep_strain.md) creep_strain()
[creep_strresult_creep_strain_X.md) creep_strain_X()
creep_strain_XY creep_strain_XY()
creep_strain_XZ creep_strain_XZ()
[creep_strain_lt_creep_strain_Y.md) creep_strain_Y()
creep_strain_YZ creep_strain_YZ()
creep_strain_Z creep_strain_Z()
[creep_strain_enrators_result_creep_strain_energy_density.md) creep_strain_energy_density()
creep_strain_eqv creep_strain_eqv()
creep_strain_intensity creep_strain_intensity()
creep_strain_max_shear creep_strain_max_shear()
[creep_strain_principalult_creep_strain_principal_1.md) creep_strain_principal_1()
[creep_strain_principal_2]_creep_strain_principal_2.md) creep_strain_principal_2()
[creep_strain_princiresult_creep_strain_principal_3.md) creep_strain_principal_3()
current_density current_density()
cyclic_analytic_seqv_max Compute the maximum of the Von Mises equivalent stress that can be expected on 360 degrees ///available inputs: time_scoping (Scoping, IList int, System.Collections.IEnumerable) (optional), mesh_scoping (ScopingsContainer, Scoping, IList int, System.Collections.IEnumerable) (optional), fields_container (FieldsContainer), bool_rotate_to_global (bool) (optional), cyclic_support (CyclicSupport)
cyclic_analytic_usum_max Compute the maximum of the total deformation that can be expected on 360 degrees ///available inputs: time_scoping (Scoping, IList int, System.Collections.IEnumerable) (optional), mesh_scoping (ScopingsContainer, Scoping, IList int, System.Collections.IEnumerable) (optional), fields_container (FieldsContainer), bool_rotate_to_global (bool) (optional), cyclic_support (CyclicSupport)
cyclic_expansion Expand cyclic results from a fieldsContainer for given sets, sectors and scoping (optionals). ///available inputs: time_scoping (Scoping, IList int, System.Collections.IEnumerable) (optional), mesh_scoping (ScopingsContainer, Scoping, IList int, System.Collections.IEnumerable) (optional), fields_container (FieldsContainer), harmonic_index (Int32) (optional), bool_rotate_to_global (bool) (optional), map_size_scoping_out () (optional), normalization_factor (double) (optional), merge_stages (bool) (optional), cyclic_support (CyclicSupport), sectors_to_expand (IList int, Scoping, ScopingsContainer, System.Collections.IEnumerable) (optional), phi (double) (optional)
[density](Ans_DataProcessensity()
displacement displacement()
displacement_X displacement_X()
displacement_Y displacement_Y()
displacement_Z displacement_Z()
[div_lighthill_tensult_div_lighthill_tensor.md) div_lighthill_tensor()
[dynamic_viscoesult_dynamic_viscosity.md) dynamic_viscosity()
[elastic_strailt_elastic_strain.md) elastic_strain()
elastic_strain_X elastic_strain_X()
elastic_strain_XY elastic_strain_XY()
elastic_strain_XZ elastic_strain_XZ()
elastic_strain_Y elastic_strain_Y()
elastic_strain_YZ elastic_strain_YZ()
elastic_strain_Z elastic_strain_Z()
elastic_strain_energy_density elastic_strain_energy_density()
elastic_strain_eqv elastic_strain_eqv()
[elastic_strain_irs_result_elastic_strain_intensity.md) elastic_strain_intensity()
[elastic_straiators_result_elastic_strain_max_shear.md) elastic_strain_max_shear()
[elastic_strain_prirs_result_elastic_strain_principal_1.md) elastic_strain_principal_1()
[elastic_strain_prirs_result_elastic_strain_principal_2.md) elastic_strain_principal_2()
[elastic_strain_principal_lt_elastic_strain_principal_3.md) elastic_strain_principal_3()
[elastic_strain_rotation_berators_result_elastic_strain_rotation_by_euler_nodes.md) read Euler angles on elements from the result file and rotate the fields in the fieldsContainer. ///available inputs: fields_container (FieldsContainer) (optional), streams_container (StreamsContainer, Stream) (optional), data_sources (DataSources)
electric_field electric_field()
[electric_field_lt_electric_field_X.md) electric_field_X()
electric_field_Y electric_field_Y()
[electric_field_lt_electric_field_Z.md) electric_field_Z()
[electric_flux_density]_electric_flux_density.md) electric_flux_density()
[electric_flux_drs_result_electric_flux_density_X.md) electric_flux_density_X()
electric_flux_density_Y electric_flux_density_Y()
[electric_flux_densresult_electric_flux_density_Z.md) electric_flux_density_Z()
[electric_poteresult_electric_potential.md) electric_potential()
[element_centroidlt_element_centroids.md) element_centroids()
[element_nodals_result_element_nodal_forces.md) element_nodal_forces()
[element_orientatioult_element_orientations.md) element_orientations()
[element_orientatioesult_element_orientations_X.md) element_orientations_X()
element_orientations_Y element_orientations_Y()
element_orientations_Z element_orientations_Z()
elemental_heat_generation elemental_heat_generation()
elemental_mass elemental_mass()
elemental_volume elemental_volume()
[enf_rotation_by_euler_result_enf_rotation_by_euler_nodes.md) read Euler angles on elements from the result file and rotate the fields in the fieldsContainer. ///available inputs: fields_container (FieldsContainer) (optional), streams_container (StreamsContainer, Stream) (optional), data_sources (DataSources)
[enthalpy](Ans_DataProc enthalpy()
[entropy](Ans_DataProcessing_py()
[epsilon](Ans_DataPro epsilon()
equivalent_mass equivalent_mass()
[equivalent_radiated_powult_equivalent_radiated_power.md) Compute the Equivalent Radiated Power (ERP) ///available inputs: fields_container (FieldsContainer), mesh (MeshedRegion, MeshesContainer), time_scoping (Int32, IList int, Scoping, System.Collections.IEnumerable), mass_density (double), speed_of_sound (double), erp_type (Int32), boolean (bool), factor (double)
[eqv_stress_parameter]_eqv_stress_parameter.md) eqv_stress_parameter()
erp_radiation_efficiency Compute the radiation efficiency (enhanced erp divided by classical erp) ///available inputs: fields_container (FieldsContainer), mesh (MeshedRegion, MeshesContainer), time_scoping (Int32, IList int, Scoping, System.Collections.IEnumerable), mass_density (double), speed_of_sound (double)
[euler_load_bucklsult_euler_load_buckling.md) Computing Euler's Critical Load. Formula: Ncr = nEIpipi /(L*L) ///available inputs: field_beam_end_condition (DataSources, Field), field_beam_moment_inertia (Field), field_beam_young_modulus (Field), field_beam_length (Field)
euler_nodes Reads a field made of 3 coordinates and 3 Euler angles (6 dofs) by node from the result file. ///available inputs: streams_container (StreamsContainer, Stream) (optional), data_sources (DataSources), filter_zeros (bool), coord_and_euler (bool), mesh (MeshedRegion) (optional)
fluid_velocity fluid_velocity()
[gasket_inelastic_c_result_gasket_inelastic_closure.md) gasket_inelastic_closure()
[gasket_inelastic_clo_result_gasket_inelastic_closure_X.md) gasket_inelastic_closure_X()
[gasket_inelastic_closure_Xlt_gasket_inelastic_closure_XY.md) gasket_inelastic_closure_XY()
[gasket_inelastic_closure_XZ]_gasket_inelastic_closure_XZ.md) gasket_inelastic_closure_XZ()
[gasket_stress](Ans_DataProcessing_operatt_stress()
gasket_stress_X gasket_stress_X()
[gasket_stresesult_gasket_stress_XY.md) gasket_stress_XY()
gasket_stress_XZ gasket_stress_XZ()
[gasket_thermal_cloesult_gasket_thermal_closure.md) gasket_thermal_closure()
[gasket_thermal_clo_result_gasket_thermal_closure_X.md) gasket_thermal_closure_X()
gasket_thermal_closure_XY gasket_thermal_closure_XY()
gasket_thermal_closure_XZ gasket_thermal_closure_XZ()
gasket_total_closure gasket_total_closure()
[gasket_total_closure_lt_gasket_total_closure_X.md) gasket_total_closure_X()
[gasket_total_cors_result_gasket_total_closure_XY.md) gasket_total_closure_XY()
[gasket__operators_result_gasket_total_closure_XZ.md) gasket_total_closure_XZ()
[global_added_mault_global_added_mass.md) Read Global Added Mass (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
[global_added_masresult_global_added_mass_pct.md) Read Global Added Mass (percentage) (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
global_center_mass Read Global Center of Mass (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
global_energy_ratio Read Global Energy Ratio (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
[global_eneing_operators_result_global_energy_ratio_wo_eroded.md) Read Global Energy ratio without Eroded Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
[global_eroding_operators_result_global_eroded_hourglass_energy.md) Read Global Eroded Hourglass Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
[global_erodng_operators_result_global_eroded_internal_energy.md) Read Global Eroded Internal Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
[global_eroded_kinetic_enerult_global_eroded_kinetic_energy.md) Read Global Eroded Kinetic Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
[global_external_woult_global_external_work.md) Read Global External Work (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
[global_hourglass_enesult_global_hourglass_energy.md) Read Global Hourglass Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
[global_internal_enerult_global_internal_energy.md) Read Global Internal Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
global_joint_internal_energy Read Global Joint Internal Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
global_kinetic_energy Read Global Kinetic Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
[global_rigid_body_serators_result_global_rigid_body_stopper_energy.md) Read Global Rigid Body Stopper Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
[global_sliding_interface_eresult_global_sliding_interface_energy.md) Read Global Sliding Interface Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
[global_springperators_result_global_spring_damper_energy.md) Read Global Spring and Damper Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
[global_system_dampinrs_result_global_system_damping_energy.md) Read Global System Damping Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
global_time_step Read Global Time Step (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
global_total_energy Read Global Total Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
[global_total_mass]_global_total_mass.md) Read Global Total Mass (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
global_velocity Read Global Velocity (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), unit_system (Int32, string) (optional)
heat_flux heat_flux()
[heat_flux_X](Ans_DataProcess heat_flux_X()
[heat_flux_Y](Ans_DataProcess heat_flux_Y()
[heat_flux_Zt_heat_flux_Z.md) heat_flux_Z()
[hydrostatic_pressure]_hydrostatic_pressure.md) hydrostatic_pressure()
[incremental__result_incremental_energy.md) incremental_energy()
[initial_coordiresult_initial_coordinates.md) initial_coordinates()
input_sound_power input_sound_power()
interface_contact_area Read Interface Contact Area (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), entity_scoping (Scoping) (optional), unit_system (Int32, string) (optional)
[interface_erators_result_interface_contact_force.md) Read Interface Contact Force (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), entity_scoping (Scoping) (optional), unit_system (Int32, string) (optional)
[interface_cotors_result_interface_contact_mass.md) Read Interface Contact Mass (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), entity_scoping (Scoping) (optional), unit_system (Int32, string) (optional)
[interface_contacts_result_interface_contact_moment.md) Read Interface Contact Moment (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), entity_scoping (Scoping) (optional), unit_system (Int32, string) (optional)
[interface_resultant_contact_forult_interface_resultant_contact_force.md) Read Interface Resultant Contact Force (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), entity_scoping (Scoping) (optional), unit_system (Int32, string) (optional)
[joint_force_reactiont_joint_force_reaction.md) joint_force_reaction()
[joint_moerators_result_joint_moment_reaction.md) joint_moment_reaction()
joint_relative_acceleration joint_relative_acceleration()
joint_relative_angular_acceleration joint_relative_angular_acceleration()
joint_relative_angular_velocity joint_relative_angular_velocity()
joint_relative_displacement joint_relative_displacement()
joint_relative_rotation joint_relative_rotation()
joint_relative_velocity joint_relative_velocity()
kinetic_energy kinetic_energy()
layer_orientation_provider Read the layer orientations. ///available inputs: streams (StreamsContainer) (optional), data_sources (DataSources)
mach_number mach_number()
magnetic_field magnetic_field()
magnetic_field_X magnetic_field_X()
magnetic_field_Y magnetic_field_Y()
magnetic_field_Z magnetic_field_Z()
magnetic_flux_density magnetic_flux_density()
magnetic_flux_density_X magnetic_flux_density_X()
magnetic_flux_density_Y magnetic_flux_density_Y()
magnetic_flux_density_Z magnetic_flux_density_Z()
magnetic_scalar_potential magnetic_scalar_potential()
magnetic_vector_potential magnetic_vector_potential()
mapdl_material_properties Read the values of the properties of a material for a given materials property field (property field that contains materials information for each element of a mesh).It returns a fields container containing a field for each material property, with only one value per material. The following keys can be used: Young's modulus (keys: EX, EY, EZ), Poisson's ratio (keys: NUXY, NUYZ, NUXZ), Shear Modulus (keys: GXY, GYZ, GXZ), Coefficient of Thermal Expansion (keys: ALPX, ALPY, ALPZ), Volumic Mass (key: DENS), second Lame's coefficient (key: MU), Damping coefficient (key: DAMP), thermal Conductivity (keys: KXX, KYY, KZZ), Resistivity (keys: RSVX, RSVY, RSVZ), Specific heat in constant volume (key: C), Film coefficient (key: HF), Viscosity (key: VISC), Emissivity (key: EMIS). ///available inputs: properties_name (string), materials (PropertyField), streams_container (StreamsContainer), data_sources (DataSources)
mapdl_section Read the values of the section properties for a given section property field (property field that contains section information for each element of a mesh). The following keys can be used: Thickness, NumLayers. For layered elements, the following keys can be used: Thickness, MatID, Orientation, NumIntPoints. ///available inputs: properties_name (string), section (PropertyField) (optional), streams_container (StreamsContainer), data_sources (DataSources), layer_property (bool) (optional), layers_requested (IList int, System.Collections.IEnumerable) (optional)
mapdl_split_on_facet_indices Splits each Field in a FieldsContainer defined on the skin elements of a mesh according to the local facets indices of its corresponding solid element. The output FieldsContainer retains the original labels and adds a 'facet' label, which indicates at which facet of the solid mesh was the original skin element located. The facet ids are according to MAPDL convention. The scoping of the output Fields reflects the element indices in the solid mesh. ///available inputs: fields_container (FieldsContainer), property_field_new_elements_to_old (PropertyField), facet_indices (PropertyField), volume_mesh (MeshedRegion), degenerated_tets (Scoping) (optional), non_degenerated_tets (Scoping) (optional)
mapdl_split_to_acmo_facet_indices This will retain the already existing labels from the input FC and will change the facet label to now mean ACMO facet indices.Each Field in the input will be split/merged into several Fields, redistributing the data to the appropriate entity. ///available inputs: fields_container (FieldsContainer), property_fields_container_element_types (PropertyFieldsContainer)
mass_flow_rate mass_flow_rate()
mass_fraction mass_fraction()
material_property_of_element Loads the appropriate operator based on the data sources and retrieves material properties. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources)
mean_static_pressure mean_static_pressure()
mean_temperature mean_temperature()
mean_velocity mean_velocity()
members_in_bending_not_certified This operator is a non-certified example of buckling resistance verification for the bending members. It is only provided as an example if you want to develop your own compute norm operator. The results computed by this beta operator have not been certified by ANSYS. ANSYS declines all responsibility for the use of this operator. HATS Beam and irregular beams (unequal I-Beam, not-square Channel-Beam, not-square Angle L-beam, unequal hollow rectangular beam) not supported. ///available inputs: time_scoping (Scoping, IList int, Int32, System.Collections.IEnumerable) (optional), field_yield_strength (Field), class_cross_section (bool), streams (StreamsContainer) (optional), data_sources (DataSources) (optional), partial_factor (double), mesh (MeshedRegion), bending_moment_y (FieldsContainer), bending_moment_z (FieldsContainer)
members_in_compression_not_certified This operator is a non-certified example of buckling resistance verification for the compression members for Class I, 2 and 3 cross-sections. It is only provided as an example if you want to develop your own compute norm operator. The results computed by this beta operator have not been certified by ANSYS. ANSYS declines all responsibility for the use of this operator. ///available inputs: time_scoping (Scoping, IList int, Int32, System.Collections.IEnumerable) (optional), field_yield_strength (DataSources, Field), field_end_condition (DataSources, Field), streams (StreamsContainer) (optional), data_sources (DataSources) (optional), manufacture (bool), partial_factor (double), mesh (MeshedRegion), axial_force (FieldsContainer), fabrication_type (bool)
members_in_linear_compression_bending_not_certified This operator is a non-certified example of buckling resistance verification for the compression and bending members for Class I, 2 and 3 cross-sections. It is only provided as an example if you want to develop your own compute norm operator. This norm is linear summation of the utilization ratios of compression members and bending members. The results computed by this beta operator have not been certified by ANSYS. ANSYS declines all responsibility for the use of this operator. ///available inputs: time_scoping (Scoping, IList int, Int32, System.Collections.IEnumerable) (optional), field_yield_strength (Field), field_end_condition (DataSources, Field) (optional), streams (StreamsContainer) (optional), data_sources (DataSources) (optional), manufacture (bool) (optional), partial_factor (double) (optional), mesh (MeshedRegion), bending_moment_y (FieldsContainer), bending_moment_z (FieldsContainer), axial_force (FieldsContainer), class_cross_section (bool), fabrication_type (bool) (optional)
migrate_to_h5dpf Read mesh properties from the results files contained in the streams or data sources and make those properties available through a mesh selection manager in output.User can input a GenericDataContainer that will map an item to a result name. Example of Map: {{ default: wf1}, {EUL: wf2}, {ENG_SE: wf3}}. ///available inputs: h5_chunk_size (Int32, GenericDataContainer) (optional), dataset_size_compression_threshold (Int32, GenericDataContainer) (optional), h5_native_compression (Int32, DataTree, GenericDataContainer) (optional), export_floats (bool, GenericDataContainer) (optional), filename (string), comma_separated_list_of_results (string) (optional), all_time_sets (bool) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources) (optional), compression_workflow (Workflow, GenericDataContainer) (optional), filtering_workflow (Workflow, GenericDataContainer) (optional)
modal_acceleration modal_acceleration()
modal_basis modal_basis()
modal_coordinate modal_coordinate()
modal_velocity modal_velocity()
nmisc nmisc()
nodal_force nodal_force()
nodal_rotation nodal_rotation()
nodal_rotation_X nodal_rotation_X()
nodal_rotation_Y nodal_rotation_Y()
nodal_rotation_Z nodal_rotation_Z()
nodal_rotational_acceleration nodal_rotational_acceleration()
nodal_rotational_acceleration_X nodal_rotational_acceleration_X()
nodal_rotational_acceleration_Y nodal_rotational_acceleration_Y()
nodal_rotational_acceleration_Z nodal_rotational_acceleration_Z()
nodal_rotational_velocity nodal_rotational_velocity()
nodal_rotational_velocity_X nodal_rotational_velocity_X()
nodal_rotational_velocity_Y nodal_rotational_velocity_Y()
nodal_rotational_velocity_Z nodal_rotational_velocity_Z()
nodal_to_global Rotates nodal elemental results to global coordinate system ///available inputs: fieldA (Field), fieldB (Field)
node_orientations node_orientations()
node_orientations_X node_orientations_X()
node_orientations_Y node_orientations_Y()
node_orientations_Z node_orientations_Z()
normal_contact_force normal_contact_force()
normal_contact_moment normal_contact_moment()
num_surface_status_changes num_surface_status_changes()
omega omega()
output_sound_power output_sound_power()
part_added_mass Read Part Added Mass (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), entity_scoping (Scoping) (optional), unit_system (Int32, string) (optional)
part_eroded_internal_energy Read Part Eroded Internal Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), entity_scoping (Scoping) (optional), unit_system (Int32, string) (optional)
part_eroded_kinetic_energy Read Part Eroded Kinetic Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), entity_scoping (Scoping) (optional), unit_system (Int32, string) (optional)
part_hourglass_energy Read Part Hourglass Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), entity_scoping (Scoping) (optional), unit_system (Int32, string) (optional)
part_internal_energy Read Part Internal Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), entity_scoping (Scoping) (optional), unit_system (Int32, string) (optional)
part_kinetic_energy Read Part Kinetic Energy (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), entity_scoping (Scoping) (optional), unit_system (Int32, string) (optional)
part_momentum Read Part Momentum (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), entity_scoping (Scoping) (optional), unit_system (Int32, string) (optional)
part_rigid_body_velocity Read Part Rigid Body Velocity (LSDyna) by calling the readers defined by the datasources. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources), entity_scoping (Scoping) (optional), unit_system (Int32, string) (optional)
plastic_state_variable plastic_state_variable()
plastic_strain plastic_strain()
plastic_strain_X plastic_strain_X()
plastic_strain_XY plastic_strain_XY()
plastic_strain_XZ plastic_strain_XZ()
plastic_strain_Y plastic_strain_Y()
plastic_strain_YZ plastic_strain_YZ()
plastic_strain_Z plastic_strain_Z()
plastic_strain_energy_density plastic_strain_energy_density()
plastic_strain_eqv plastic_strain_eqv()
plastic_strain_intensity plastic_strain_intensity()
plastic_strain_max_shear plastic_strain_max_shear()
plastic_strain_principal_1 plastic_strain_principal_1()
plastic_strain_principal_2 plastic_strain_principal_2()
plastic_strain_principal_3 plastic_strain_principal_3()
plastic_strain_rotation_by_euler_nodes read Euler angles on elements from the result file and rotate the fields in the fieldsContainer. ///available inputs: fields_container (FieldsContainer) (optional), streams_container (StreamsContainer, Stream) (optional), data_sources (DataSources)
poynting_vector Compute the Poynting Vector ///available inputs: fields_containerA (FieldsContainer), fields_containerB (FieldsContainer), fields_containerC (FieldsContainer), fields_containerD (FieldsContainer), meshed_region (MeshedRegion) (optional), int32 (Int32) (optional)
poynting_vector_surface Compute the Poynting Vector surface integral ///available inputs: fields_containerA (FieldsContainer), fields_containerB (FieldsContainer), fields_containerC (FieldsContainer), fields_containerD (FieldsContainer), meshed_region (MeshedRegion) (optional), int32 (Int32) (optional)
pressure pressure()
pretension Reads the pretension adjustment and tension force. Rotation is not allowed for these results. ///available inputs: time_scoping (ScopingsContainer, Scoping) (optional), mesh_scoping (ScopingsContainer, Scoping) (optional), fields_container (FieldsContainer) (optional), streams_container (StreamsContainer, Stream), data_sources (DataSources), mesh (MeshedRegion, MeshesContainer) (optional), read_cyclic (Int32) (optional), expanded_meshed_region (MeshedRegion, MeshesContainer) (optional), sectors_to_expand (IList int, Scoping, ScopingsContainer, System.Collections.IEnumerable) (optional), phi (double) (optional)
raw_displacement raw_displacement()
raw_reaction_force raw_reaction_force()
reaction_force reaction_force()
reaction_force_X reaction_force_X()
reaction_force_Y reaction_force_Y()
reaction_force_Z reaction_force_Z()
read_cms_rbd_file read_cms_rbd_file()
recombine_harmonic_indeces_cyclic Add the fields corresponding to different load steps with the same frequencies to compute the response. ///available inputs: fields_container (FieldsContainer), is_constant (bool) (optional)
remove_rigid_body_motion Removes rigid body mode from a total displacement field by minimization. Use a reference point in order to subtract its displacement to the result displacement field. ///available inputs: field (Field, FieldsContainer), reference_node_id (Int32) (optional), mesh (MeshedRegion) (optional)
remove_rigid_body_motion_fc Removes rigid body mode from a total displacement field by minimization. Use a reference point in order to subtract its displacement to the result displacement field. ///available inputs: fields_container (FieldsContainer), reference_node_id (Int32) (optional), mesh (MeshedRegion) (optional)
result_provider result_provider()
rigid_transformation Extracts rigid body motions from a displacement in input. ///available inputs: streams_container (StreamsContainer) (optional), data_sources (DataSources)
rigid_transformation_provider Extracts rigid body transformation from dsub file. ///available inputs: streams (Stream) (optional), data_sources (DataSources)
rms_static_pressure rms_static_pressure()
rms_temperature rms_temperature()
rms_velocity rms_velocity()
rom_data_provider Set the required data for the invariant terms computation (reduced matrices, lumped mass matrix, modes ...) ///available inputs: rom_type (bool), reduced_stiff_matrix (FieldsContainer), reduced_damping_matrix (FieldsContainer), reduced_mass_matrix (FieldsContainer), data_sources (DataSources), reduced_rhs_vector (FieldsContainer), lumped_mass_matrix (FieldsContainer), mode_shapes (FieldsContainer)
smisc smisc()
specific_heat specific_heat()
spectrum_data Read spectral data from the result files contained in the streams or data sources. ///available inputs: streams (StreamsContainer) (optional), data_sources (DataSources)
squared_l2norm_pressure squared_l2norm_pressure()
state_variable state_variable()
static_pressure static_pressure()
stiffness_matrix_energy stiffness_matrix_energy()
strain_eqv_as_mechanical Computes the equivalent (Von Mises) elastic strains and averages it to the nodes (by default). For multibody simulations, averaging across bodies can either be activated or deactivated. ///available inputs: time_scoping (Scoping, IList int, System.Collections.IEnumerable) (optional), mesh_scoping (Scoping, ScopingsContainer) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources), mesh (MeshedRegion, MeshesContainer) (optional), requested_location (string) (optional), poisson_ratio (Int32, double) (optional), read_cyclic (bool) (optional), average_across_bodies (bool) (optional)
strain_eqv_as_mechanical_workflow Generates a workflow that computes the equivalent (Von Mises) elastic strains and averages it to the nodes (by default). For multibody simulations, averaging across bodies can either be activated or deactivated. ///available inputs: time_scoping (Scoping, IList int, System.Collections.IEnumerable) (optional), mesh_scoping (Scoping, ScopingsContainer) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources), mesh (MeshedRegion, MeshesContainer) (optional), requested_location (string) (optional), read_cyclic (bool) (optional), average_across_bodies (bool) (optional)
stress stress()
stress_X stress_X()
stress_XY stress_XY()
stress_XZ stress_XZ()
stress_Y stress_Y()
stress_YZ stress_YZ()
stress_Z stress_Z()
stress_eqv_as_mechanical Computes the equivalent (Von Mises) stresses and averages it to the nodes (by default). For multibody simulations, averaging across bodies can either be activated or deactivated. ///available inputs: time_scoping (Scoping, IList int, System.Collections.IEnumerable) (optional), mesh_scoping (Scoping, ScopingsContainer) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources), mesh (MeshedRegion, MeshesContainer) (optional), requested_location (string) (optional), read_cyclic (bool) (optional), average_across_bodies (bool) (optional)
stress_eqv_as_mechanical_workflow Generates a workflow that computes the equivalent (Von Mises) stresses and averages it to the nodes (by default). For multibody simulations, averaging across bodies can either be activated or deactivated. ///available inputs: time_scoping (Scoping, IList int, System.Collections.IEnumerable) (optional), mesh_scoping (Scoping, ScopingsContainer) (optional), streams_container (StreamsContainer) (optional), data_sources (DataSources), mesh (MeshedRegion, MeshesContainer) (optional), requested_location (string) (optional), read_cyclic (bool) (optional), average_across_bodies (bool) (optional)
stress_intensity stress_intensity()
stress_max_shear stress_max_shear()
stress_principal_1 stress_principal_1()
stress_principal_2 stress_principal_2()
stress_principal_3 stress_principal_3()
stress_ratio stress_ratio()
stress_rotation_by_euler_nodes read Euler angles on elements from the result file and rotate the fields in the fieldsContainer. ///available inputs: fields_container (FieldsContainer) (optional), streams_container (StreamsContainer, Stream) (optional), data_sources (DataSources)
stress_von_mises stress_von_mises()
structural_temperature structural_temperature()
superficial_velocity superficial_velocity()
surface_heat_rate surface_heat_rate()
swelling_strains swelling_strains()
tangential_contact_force tangential_contact_force()
tangential_contact_moment tangential_contact_moment()
temperature temperature()
temperature_grad temperature_grad()
temperature_grad_X temperature_grad_X()
temperature_grad_Y temperature_grad_Y()
temperature_grad_Z temperature_grad_Z()
thermal_conductivity thermal_conductivity()
thermal_dissipation_energy thermal_dissipation_energy()
thermal_strain thermal_strain()
thermal_strain_X thermal_strain_X()
thermal_strain_XY thermal_strain_XY()
thermal_strain_XZ thermal_strain_XZ()
thermal_strain_Y thermal_strain_Y()
thermal_strain_YZ thermal_strain_YZ()
thermal_strain_Z thermal_strain_Z()
thermal_strain_principal_1 thermal_strain_principal_1()
thermal_strain_principal_2 thermal_strain_principal_2()
thermal_strain_principal_3 thermal_strain_principal_3()
thermal_strains_eqv thermal_strains_eqv()
thickness thickness()
torque Compute torque of a force based on a 3D point. ///available inputs: fields_container (FieldsContainer), spoint (Field, FieldsContainer)
total_contact_force total_contact_force()
total_contact_moment total_contact_moment()
total_mass Reads total mass from mode file. ///available inputs: data_sources (DataSources)
total_pressure total_pressure()
total_strain total_strain()
total_temperature total_temperature()
transform_invariant_terms_rbd transform_invariant_terms_rbd()
transient_rayleigh_integration Computes the transient Rayleigh integral ///available inputs: fields_container (FieldsContainer), mesh (MeshedRegion, MeshesContainer), time_scoping (Int32, IList int, Scoping, System.Collections.IEnumerable), field (Field), observation_mesh (MeshedRegion), mass_density (double), speed_of_sound (double)
turbulent_kinetic_energy turbulent_kinetic_energy()
turbulent_viscosity turbulent_viscosity()
velocity velocity()
velocity_X velocity_X()
velocity_Y velocity_Y()
velocity_Z velocity_Z()
volume_fraction volume_fraction()
wall_shear_stress wall_shear_stress()
workflow_energy_per_component Calculates the cumulated energy per component (Named Selection). For cyclic and multistage models, the expansion will be automatically done. ///available inputs: time_scoping (Scoping) (optional), mesh_scoping (Scoping, ScopingsContainer) (optional), energy_type (Int32) (optional), streams_container (StreamsContainer), data_sources (DataSources), named_selection1 (string) (optional), named_selection2 (string) (optional)
workflow_energy_per_harmonic Calculates the cumulated energy per harmonic in a multistage multiharmonic model. ///available inputs: time_scoping (Scoping) (optional), mesh_scoping (Scoping) (optional), energy_type (Int32) (optional), stream (Stream), data_sources (DataSources)
write_cms_rbd_file write_cms_rbd_file()
write_motion_dfmf_file write_motion_dfmf_file()
y_plus y_plus()

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