SCHEMA epicentre_extensions; REFERENCE FROM epicentre; TYPE ndt_absolute_orientation_array = element('grid','node','angular direction',6); END_TYPE; TYPE ndt_absorbed_dose = quantity('absorbed dose',6); END_TYPE; TYPE ndt_acceleration_linear = quantity('acceleration linear',6); END_TYPE; TYPE ndt_acceleration_rotational = quantity('acceleration rotational',6); END_TYPE; TYPE ndt_accurate_length = quantity('length',10); END_TYPE; TYPE ndt_acoustic_impedance = quantity('acoustic impedance',6); END_TYPE; TYPE ndt_acoustical_energy = quantity('acoustical energy',6); END_TYPE; TYPE ndt_acoustical_intensity = quantity('acoustical intensity',6); END_TYPE; TYPE ndt_acoustical_power = quantity('acoustical power',6); END_TYPE; TYPE ndt_acquisition_index_array = element('grid','node','',6); END_TYPE; TYPE ndt_address_email = STRING(80); END_TYPE; TYPE ndt_admittance = quantity('admittance',6); END_TYPE; TYPE ndt_amount_of_substance = quantity('amount of substance',6); END_TYPE; TYPE ndt_amplitude_1d_value = element('grid1d','node','amplitude',6); END_TYPE; TYPE ndt_angular_direction = element('grid1d','node','angular direction',6); END_TYPE; TYPE ndt_angular_velocity = quantity('angular velocity',6); END_TYPE; TYPE ndt_any_quantity = anyquantity(14); END_TYPE; TYPE ndt_area = quantity('area',6); END_TYPE; TYPE ndt_area_per_mass = quantity('area per mass',6); END_TYPE; TYPE ndt_area_per_volume = quantity('area per volume',6); END_TYPE; TYPE ndt_axis_coordinates = element('grid1d','node','',6); END_TYPE; TYPE ndt_azimuth = point('azimuthal angle','',6,6); END_TYPE; TYPE ndt_bending_moment_per_length = quantity('bending moment per length',6); END_TYPE; TYPE ndt_bin_index_array = element('grid','node','bin node index',6); END_TYPE; TYPE ndt_boolean = BOOLEAN; END_TYPE; TYPE ndt_bubble_point_pressure_curve = line('','pt system',6); END_TYPE; TYPE ndt_bubble_point_pressure_point = point('pt system','saturated fluid properties',6,6); END_TYPE; TYPE ndt_calorific_value_gas_volume = quantity('calorific value gas volume',6); END_TYPE; TYPE ndt_calorific_value_mass_basis = quantity('calorific value mass basis',6); END_TYPE; TYPE ndt_calorific_value_mole_basis = quantity('calorific value mole basis',6); END_TYPE; TYPE ndt_calorific_value_solid_liquid_vol = quantity('calorific value solid liquid vol',6); END_TYPE; TYPE ndt_capacitance = quantity('capacitance',6); END_TYPE; TYPE ndt_capillary_pressure_curve = line('','capillary pressure system',6); END_TYPE; TYPE ndt_capillary_pressure_point = location('capillary pressure system',6); END_TYPE; TYPE ndt_capture_unit = quantity('capture unit',6); END_TYPE; TYPE ndt_charge_density = quantity('charge density',6); END_TYPE; TYPE ndt_code1 = STRING(1) FIXED; END_TYPE; TYPE ndt_code2 = STRING(2) FIXED; END_TYPE; TYPE ndt_comment = STRING(2000); END_TYPE; TYPE ndt_comment_array = element('grid','node','comment only',0); END_TYPE; TYPE ndt_compaction_factor_curve = line('','compaction factor system',6); END_TYPE; TYPE ndt_compaction_factor_point = point('compaction factor system','compaction factor',6,6); END_TYPE; TYPE ndt_compressibility = quantity('compressibility',6); END_TYPE; TYPE ndt_concentration_mass_per_mass = quantity('concentration mass per mass',6); END_TYPE; TYPE ndt_concentration_mass_per_volume = quantity('concentration mass per volume',6); END_TYPE; TYPE ndt_concentration_mole_per_volume = quantity('concentration mole per volume',6); END_TYPE; TYPE ndt_concentration_volume_per_mole = quantity('concentration volume per mole',6); END_TYPE; TYPE ndt_concentration_volume_per_volume = quantity('concentration volume per volume',6); END_TYPE; TYPE ndt_conductance = quantity('conductance',6); END_TYPE; TYPE ndt_conductivity = quantity('conductivity',6); END_TYPE; TYPE ndt_cooling_duty = quantity('cooling duty',6); END_TYPE; TYPE ndt_corrosion_rate = quantity('corrosion rate',6); END_TYPE; TYPE ndt_cum_tank_vol_with_height = line('grid','volume length',6); END_TYPE; TYPE ndt_current_density = quantity('current density',6); END_TYPE; TYPE ndt_current_density_linear = quantity('current density linear',6); END_TYPE; TYPE ndt_Darcy_flow_coefficient = quantity('Darcy flow coefficient',6); END_TYPE; TYPE ndt_data_store_type = ENUMERATION OF ( DATA_STORE, STAGED_DATA_STORE ); END_TYPE; TYPE ndt_date = date; END_TYPE; TYPE ndt_date_tod = timestamp(2); END_TYPE; TYPE ndt_day_interval = daytimeinterval(2); END_TYPE; TYPE ndt_decibel_per_octave = quantity('decibel per octave',6); END_TYPE; TYPE ndt_density_gas = quantity('density gas',6); END_TYPE; TYPE ndt_density_gradient = quantity('density gradient',6); END_TYPE; TYPE ndt_density_liquid = quantity('density liquid',6); END_TYPE; TYPE ndt_density_molar = quantity('concentration volume per mole',6); END_TYPE; TYPE ndt_density_solid = quantity('density solid',6); END_TYPE; TYPE ndt_dew_point_pressure_curve = line('','pt system',6); END_TYPE; TYPE ndt_dew_point_pressure_point = point('pt system','saturated fluid properties',6,6); END_TYPE; TYPE ndt_diffusivity = quantity('diffusivity',6); END_TYPE; TYPE ndt_displacement = quantity('displacement',6); END_TYPE; TYPE ndt_dry_gas_fvf_curve = volume('','pt dry gas beta factor system',6); END_TYPE; TYPE ndt_dry_gas_fvf_point = point('pt dry gas beta factor system','',6,6); END_TYPE; TYPE ndt_dry_gas_pressure_curve = surface('','pt dry gas system',6); END_TYPE; TYPE ndt_dry_gas_pressure_point = point('','dry gas properties',6,6); END_TYPE; TYPE ndt_dry_gas_viscosity_curve = volume('','pt dry gas viscosity system',6); END_TYPE; TYPE ndt_dry_gas_viscosity_point = point('pt dry gas viscosity system','',6,6); END_TYPE; TYPE ndt_dry_gas_z_factor_curve = volume('','pt dry gas z factor system',6); END_TYPE; TYPE ndt_dry_gas_z_factor_point = point('pt dry gas z factor system','',6,6); END_TYPE; TYPE ndt_earth_angle = angle('plane angle',9); END_TYPE; TYPE ndt_edge_geometry_uncertainty = element('grid1d','node','position uncertainty',6); END_TYPE; TYPE ndt_elastic_modulus = quantity('elastic modulus',6); END_TYPE; TYPE ndt_electric_capacity = quantity('electric capacity',6); END_TYPE; TYPE ndt_electric_charge = quantity('electric charge',6); END_TYPE; TYPE ndt_electric_current = quantity('electric current',6); END_TYPE; TYPE ndt_electric_dipole_moment = quantity('electric dipole moment',6); END_TYPE; TYPE ndt_electric_field_strength = quantity('electric field strength',6); END_TYPE; TYPE ndt_electric_flux = quantity('electric flux',6); END_TYPE; TYPE ndt_electric_impedance = quantity('electric impedance',6); END_TYPE; TYPE ndt_electric_polarization = quantity('electric polarization',6); END_TYPE; TYPE ndt_electric_potential = quantity('electric potential',6); END_TYPE; TYPE ndt_electric_resistivity = quantity('electrical resistivity',6); END_TYPE; TYPE ndt_electromotive_force = quantity('electromotive force',6); END_TYPE; TYPE ndt_element_kind = ENUMERATION OF ( ELEMENT_KIND_NODE, ELEMENT_KIND_FACE, ELEMENT_KIND_EDGE, ELEMENT_KIND_CELL ); END_TYPE; TYPE ndt_element_representation = ENUMERATION OF ( TRIMESH, GRID1D, GRID2D, GRID3D, GRID4D, GRID5D, GRID6D, GRID7D, GRID8D, GRID9D, GRID10D, GRID11D, GRID12D, GRID13D, GRID14D, GRID15D ); END_TYPE; TYPE ndt_elevation = quantity('length',6); END_TYPE; TYPE ndt_energy = quantity('energy',6); END_TYPE; TYPE ndt_energy_per_mass = quantity('energy per mass',6); END_TYPE; TYPE ndt_energy_per_volume = quantity('energy per volume',6); END_TYPE; TYPE ndt_event_observation_array = element('grid','node','event observation',6); END_TYPE; TYPE ndt_fail_state = ENUMERATION OF ( WARN, MARK, ABORT, FIXUP ); END_TYPE; TYPE ndt_fault_slip_element = element('','','fault slip',6); END_TYPE; TYPE ndt_flow_rate_mass_basis = quantity('flow rate mass basis',6); END_TYPE; TYPE ndt_flow_rate_mole_basis = quantity('flow rate mole basis',6); END_TYPE; TYPE ndt_flow_rate_per_area_mass_basis = quantity('flow rate per area mass basis',6); END_TYPE; TYPE ndt_flow_rate_per_area_mole_basis = quantity('flow rate per area mole basis',6); END_TYPE; TYPE ndt_flow_rate_per_area_volume_basis = quantity('flow rate per area volume basis',6); END_TYPE; TYPE ndt_flow_rate_per_length_mass_basis = quantity('flow rate per length mass basis',6); END_TYPE; TYPE ndt_flow_rate_per_length_volume_basis = quantity('flow rate per length volume basis',6); END_TYPE; TYPE ndt_flow_rate_volume_basis = quantity('flow rate volume basis',6); END_TYPE; TYPE ndt_fluid_phase_component_element = element('','','fluid phase component',6); END_TYPE; TYPE ndt_fluid_phase_element = element('','','fluid phase',6); END_TYPE; TYPE ndt_fluid_phase_interface_element = element('','','fluid phase interface',6); END_TYPE; TYPE ndt_fluid_rheology = line('grid','fluid rheology',6); END_TYPE; TYPE ndt_fluid_stress = quantity('fluid stress',6); END_TYPE; TYPE ndt_flux_of_displacement = quantity('flux of displacement',6); END_TYPE; TYPE ndt_force = quantity('force',6); END_TYPE; TYPE ndt_force_area = quantity('force area',6); END_TYPE; TYPE ndt_force_per_length = quantity('force per length',6); END_TYPE; TYPE ndt_frequency = quantity('frequency',6); END_TYPE; TYPE ndt_frequency_1d_index = line('','frequency 1d',6); END_TYPE; TYPE ndt_frequency_spectrum_1d_value = element('grid1d','node','frequency spectrum',6); END_TYPE; TYPE ndt_fuel_consumption = quantity('fuel consumption',6); END_TYPE; TYPE ndt_fuel_mileage = quantity('fuel mileage',6); END_TYPE; TYPE ndt_gel_strength = line('grid','gel strength',6); END_TYPE; TYPE ndt_geoidal_undulation = surface('','geoidal undulation system',9); END_TYPE; TYPE ndt_geometry_1d_edge = line('','geometry 1d',10); END_TYPE; TYPE ndt_geometry_2d_edge = line('','geometry 2d',10); END_TYPE; TYPE ndt_geometry_2d_face = surface('','geometry 2d',10); END_TYPE; TYPE ndt_geometry_2d_ring = line('grid','geometry 2d',10); END_TYPE; TYPE ndt_geometry_3d_edge = line('','geometry 3d',10); END_TYPE; TYPE ndt_geometry_3d_face = surface('','geometry 3d',10); END_TYPE; TYPE ndt_geometry_3d_region = volume('','geometry 3d',10); END_TYPE; TYPE ndt_geometry_3d_ring = line('grid','geometry 3d',10); END_TYPE; TYPE ndt_geometry_3d_shell = surface('trimesh','geometry 3d',10); END_TYPE; TYPE ndt_gor_curve = line('','pt rs system',6); END_TYPE; TYPE ndt_gor_point = point('pt rs system','',6,6); END_TYPE; TYPE ndt_heat_flow_unit = quantity('heat flow unit',6); END_TYPE; TYPE ndt_heat_flux = quantity('heat flux',6); END_TYPE; TYPE ndt_heat_generation_unit = quantity('heat generation unit',6); END_TYPE; TYPE ndt_heat_release_rate = quantity('heat release rate',6); END_TYPE; TYPE ndt_heat_transfer_coefficient = quantity('heat transfer coefficient',6); END_TYPE; TYPE ndt_identifier = STRING(50); END_TYPE; TYPE ndt_illuminance = quantity('illuminance',6); END_TYPE; TYPE ndt_impact_energy = quantity('impact energy',6); END_TYPE; TYPE ndt_inflow_performance_ratio = quantity('inflow performance ratio',6); END_TYPE; TYPE ndt_instance_status = ENUMERATION OF ( current, provisional, deprecated ); END_TYPE; TYPE ndt_int1 = INTEGER; END_TYPE; TYPE ndt_int4 = INTEGER; END_TYPE; TYPE ndt_integer_element = element('grid','cell','cell number',0); END_TYPE; TYPE ndt_interfacial_tension_curve = volume('','pt interfacial tension system',6); END_TYPE; TYPE ndt_interfacial_tension_point = point('pt interfacial tension system','',6,6); END_TYPE; TYPE ndt_interval_transit_time = quantity('interval transit time',6); END_TYPE; TYPE ndt_irradiance = quantity('irradiance',6); END_TYPE; TYPE ndt_k_value_curve = surface('','pt k value system',6); END_TYPE; TYPE ndt_k_value_point = location('pt k value system',6); END_TYPE; TYPE ndt_latent_heat_of_vaporization = quantity('latent heat',6); END_TYPE; TYPE ndt_length = quantity('length',6); END_TYPE; TYPE ndt_length_diameter = quantity('length tube diameter',6); END_TYPE; TYPE ndt_length_midrange = quantity('length midrange',6); END_TYPE; TYPE ndt_length_per_volume = quantity('length per volume',6); END_TYPE; TYPE ndt_light_exposure = quantity('light exposure',6); END_TYPE; TYPE ndt_line = line('','',6); END_TYPE; TYPE ndt_line_representation = ENUMERATION OF ( GRID ); END_TYPE; TYPE ndt_linear_thermal_expansion = quantity('linear thermal expansion',6); END_TYPE; TYPE ndt_location = location('',10); END_TYPE; TYPE ndt_location_1d = location('earth 1d',10); END_TYPE; TYPE ndt_location_2d = location('earth 2d',10); END_TYPE; TYPE ndt_location_3d = location('earth 3d',10); END_TYPE; TYPE ndt_logical = LOGICAL; END_TYPE; TYPE ndt_logical_array = element('grid','node','logical flag',1); END_TYPE; TYPE ndt_long_name = STRING(80); END_TYPE; TYPE ndt_long_sql = STRING; END_TYPE; TYPE ndt_luminance = quantity('luminance',6); END_TYPE; TYPE ndt_luminous_efficacy = quantity('luminous efficacy',6); END_TYPE; TYPE ndt_luminous_exitance = quantity('luminous exitance',6); END_TYPE; TYPE ndt_luminous_flux = quantity('luminous flux',6); END_TYPE; TYPE ndt_luminous_intensity = quantity('luminous intensity',6); END_TYPE; TYPE ndt_magnetic_dipole_moment = quantity('magnetic dipole moment',6); END_TYPE; TYPE ndt_magnetic_field_strength = quantity('magnetic field strength',6); END_TYPE; TYPE ndt_magnetic_flux = quantity('magnetic flux',6); END_TYPE; TYPE ndt_magnetic_flux_density = quantity('magnetic flux density',6); END_TYPE; TYPE ndt_magnetic_moment = quantity('magnetic moment',6); END_TYPE; TYPE ndt_magnetic_potential_difference = quantity('magnetic potential difference',6); END_TYPE; TYPE ndt_magnetization = quantity('magnetization',6); END_TYPE; TYPE ndt_mass = quantity('mass',6); END_TYPE; TYPE ndt_mass_per_area = quantity('mass per area',6); END_TYPE; TYPE ndt_mass_per_length = quantity('mass per length',6); END_TYPE; TYPE ndt_measured_depth = location('measured depth system',6); END_TYPE; TYPE ndt_mesh_edge = sample('mesh edge',6); END_TYPE; TYPE ndt_mesh_face = sample('mesh face',6); END_TYPE; TYPE ndt_missing_element = element('','','',6); END_TYPE; TYPE ndt_mobility = quantity('mobility',6); END_TYPE; TYPE ndt_mod_k_value_curve = surface('','pt mod k value system',6); END_TYPE; TYPE ndt_modulus_of_admittance = quantity('modulus of admittance',6); END_TYPE; TYPE ndt_modulus_of_impedance = quantity('modulus of impedance',6); END_TYPE; TYPE ndt_moh_scale_hardness = INTEGER; END_TYPE; TYPE ndt_mole_fraction_curve = surface('','pt mole fractions',6); END_TYPE; TYPE ndt_mole_fraction_point = point('pt mole fractions','',6,6); END_TYPE; TYPE ndt_moment_of_inertia = quantity('moment of inertia',6); END_TYPE; TYPE ndt_moment_of_section = quantity('moment of section',6); END_TYPE; TYPE ndt_momentum = quantity('momentum',6); END_TYPE; TYPE ndt_money = money(''); END_TYPE; TYPE ndt_name = STRING(40); END_TYPE; TYPE ndt_name_array = element('grid','node','name only',6); END_TYPE; TYPE ndt_non_darcy_flow_coefficient = quantity('',6); END_TYPE; TYPE ndt_number_array = element('grid','node','whole number',6); END_TYPE; TYPE ndt_parachor = quantity('parachor',6); END_TYPE; TYPE ndt_per_area = quantity('per area',6); END_TYPE; TYPE ndt_percent = REAL(6); END_TYPE; TYPE ndt_percent_le_100 = REAL(6); WHERE percent : (self <= 100) and (self >=0); END_TYPE; TYPE ndt_permeability = quantity('permeability',6); END_TYPE; TYPE ndt_permeability_length = quantity('permeability length',6); END_TYPE; TYPE ndt_permeance = quantity('permeance',6); END_TYPE; TYPE ndt_permittivity = quantity('permittivity',6); END_TYPE; TYPE ndt_pfrac_le_1 = REAL(6); WHERE pfrac : (self <= 1) and (self >= 0); END_TYPE; TYPE ndt_ph = quantity('pH',6); END_TYPE; TYPE ndt_phone_number = STRING(10); END_TYPE; TYPE ndt_pint1 = INTEGER; WHERE pint1 : self >= 0; END_TYPE; TYPE ndt_pint2 = INTEGER; WHERE pint2 : self >= 0; END_TYPE; TYPE ndt_pint4 = INTEGER; WHERE pint4 : self >= 0; END_TYPE; TYPE ndt_plane_angle = quantity('plane angle',6); END_TYPE; TYPE ndt_point = point('','',6,6); END_TYPE; TYPE ndt_point_geometry_uncertainty = sample('position uncertainty',6); END_TYPE; TYPE ndt_porosity = quantity('porosity',6); END_TYPE; TYPE ndt_power = quantity('power',6); END_TYPE; TYPE ndt_power_per_area = quantity('power per area',6); END_TYPE; TYPE ndt_preal4 = REAL(6); WHERE preal4 : self >= 0; END_TYPE; TYPE ndt_pressure = quantity('pressure',6); END_TYPE; TYPE ndt_pressure_drop = quantity('pressure drop',6); END_TYPE; TYPE ndt_privilege = ENUMERATION OF ( DAE_SELECT, DAE_INSERT, DAE_UPDATE, DAE_DELETE, DAE_EXECUTE ); END_TYPE; TYPE ndt_productivity_index = quantity('productivity index',6); END_TYPE; TYPE ndt_property_element = element('','','',6); END_TYPE; TYPE ndt_pseudo_pressure = quantity('pseudopressure',6); END_TYPE; TYPE ndt_radiance = quantity('radiance',6); END_TYPE; TYPE ndt_radiant_energy = quantity('radiant energy',6); END_TYPE; TYPE ndt_radiant_flux = quantity('radiant flux',6); END_TYPE; TYPE ndt_radiant_intensity = quantity('radiant intensity',6); END_TYPE; TYPE ndt_radioactivity = quantity('radioactivity',6); END_TYPE; TYPE ndt_ratio = ratio(6); END_TYPE; TYPE ndt_rational = rational; END_TYPE; TYPE ndt_reactance = quantity('reactance',6); END_TYPE; TYPE ndt_real4 = REAL(6); END_TYPE; TYPE ndt_real8 = REAL(14); END_TYPE; TYPE ndt_relative_length = quantity('relative length',6); END_TYPE; TYPE ndt_relative_orientation_array = element('grid','node','case orientation',6); END_TYPE; TYPE ndt_reluctance = quantity('reluctance',6); END_TYPE; TYPE ndt_resistance = quantity('resistance',6); END_TYPE; TYPE ndt_rotational_frequency = quantity('rotational frequency',6); END_TYPE; TYPE ndt_saturated_compressibility_curve = surface('','pt compressibility system',6); END_TYPE; TYPE ndt_saturated_compressibility_point = point('pt compressibility system','',6,6); END_TYPE; TYPE ndt_saturated_fvf_curve = surface('','pt beta factor system',6); END_TYPE; TYPE ndt_saturated_fvf_point = point('pt beta factor system','',6,6); END_TYPE; TYPE ndt_saturated_liquid_density_curve = surface('','pt density liquid system',6); END_TYPE; TYPE ndt_saturated_liquid_density_point = point('pt density liquid system','',6,6); END_TYPE; TYPE ndt_saturated_viscosity_curve = surface('','pt viscosity system',6); END_TYPE; TYPE ndt_saturated_viscosity_point = point('pt viscosity system','',6,6); END_TYPE; TYPE ndt_saturation_distribution_element = element('','','saturation',6); END_TYPE; TYPE ndt_saturation_gradient = quantity('volume fraction per length',6); END_TYPE; TYPE ndt_scale = quantity('ratio',6); END_TYPE; TYPE ndt_section_modulus = quantity('section modulus',6); END_TYPE; TYPE ndt_seismic_time = quantity('seismic time',6); END_TYPE; TYPE ndt_self_inductance = quantity('self inductance',6); END_TYPE; TYPE ndt_shear_rate = quantity('shear rate',6); END_TYPE; TYPE ndt_short_name = STRING(15); END_TYPE; TYPE ndt_shot_density = quantity('per length',6); END_TYPE; TYPE ndt_solid_angle = quantity('solid angle',6); END_TYPE; TYPE ndt_sound_pressure = quantity('sound pressure',6); END_TYPE; TYPE ndt_specific_fuel_consumption_mass = quantity('specific fuel consumption mass',6); END_TYPE; TYPE ndt_specific_fuel_consumption_volume = quantity('specific fuel consumption volume',6); END_TYPE; TYPE ndt_specific_heat_capacity_mass = quantity('specific heat capacity',6); END_TYPE; TYPE ndt_specific_heat_capacity_mole = quantity('specific heat capacity mole',6); END_TYPE; TYPE ndt_specific_impact_energy = quantity('specific impact energy',6); END_TYPE; TYPE ndt_specific_productivity_index = quantity('specific productivity index',6); END_TYPE; TYPE ndt_specific_volume_mass_gas = quantity('specific volume mass gas',6); END_TYPE; TYPE ndt_specific_volume_mass_liquid = quantity('specific volume mass liquid',6); END_TYPE; TYPE ndt_specific_volume_mole = quantity('specific volume mole',6); END_TYPE; TYPE ndt_spherical_coordinates_complex_angle = location('',6); END_TYPE; TYPE ndt_station_relative_location_array = element('grid','node','station relative location',6); END_TYPE; TYPE ndt_std_volume_gas = quantity('std volume gas',6); END_TYPE; TYPE ndt_std_volume_gas_rate = quantity('std volume gas rate',6); END_TYPE; TYPE ndt_std_volume_liquid = quantity('std volume liquid',6); END_TYPE; TYPE ndt_std_volume_liquid_rate = quantity('std volume liquid rate',6); END_TYPE; TYPE ndt_std_volume_per_area = quantity('std volume per area',6); END_TYPE; TYPE ndt_std_volume_per_volume = quantity('std volume per volume',6); END_TYPE; TYPE ndt_std_volume_ratio = quantity('std volume ratio',6); END_TYPE; TYPE ndt_stress = quantity('stress',6); END_TYPE; TYPE ndt_string_255 = STRING(255); END_TYPE; TYPE ndt_surface_density_of_charge = quantity('surface density of charge',6); END_TYPE; TYPE ndt_surface_energy = quantity('surface energy',6); END_TYPE; TYPE ndt_surface_representation = ENUMERATION OF ( GRID, TRIMESH, CONTOUR ); END_TYPE; TYPE ndt_susceptance = quantity('susceptance',6); END_TYPE; TYPE ndt_temperature = quantity('temperature',6); END_TYPE; TYPE ndt_temperature_per_length = quantity('temperature per length',6); END_TYPE; TYPE ndt_test_state = ENUMERATION OF ( IMMEDIATE, DEFERRED, OFF ); END_TYPE; TYPE ndt_text = STRING; END_TYPE; TYPE ndt_text_132 = STRING(132); END_TYPE; TYPE ndt_thermal_conductivity = quantity('thermal conductivity',6); END_TYPE; TYPE ndt_thermal_resistance = quantity('thermal resistance',6); END_TYPE; TYPE ndt_three_phase_rel_perm_point = location('kr 3p system',6); END_TYPE; TYPE ndt_three_phase_rel_perm_surface = surface('','kr 3p system',6); END_TYPE; TYPE ndt_time = quantity('time',6); END_TYPE; TYPE ndt_time_1d_index = line('','time 1d',6); END_TYPE; TYPE ndt_time_array = element('grid','node','time only',6); END_TYPE; TYPE ndt_time_geologic = quantity('time geologic',7); END_TYPE; TYPE ndt_time_millisecond = quantity('time millisecond',6); END_TYPE; TYPE ndt_time_second = quantity('time second',6); END_TYPE; TYPE ndt_torque = quantity('torque',6); END_TYPE; TYPE ndt_tortuosity = quantity('tortuosity',6); END_TYPE; TYPE ndt_trace_value = element('','','',6); END_TYPE; TYPE ndt_turbulence_coefficient = quantity('turbulence coefficient',6); END_TYPE; TYPE ndt_two_phase_rel_perm_curve = line('','kr 2p system',6); END_TYPE; TYPE ndt_two_phase_rel_perm_point = location('kr 2p system',6); END_TYPE; TYPE ndt_uid_array = element('grid','node','user unique identifier',6); END_TYPE; TYPE ndt_undersaturated_compressibility_curve = volume('','upt compressibility system',6); END_TYPE; TYPE ndt_undersaturated_compressibility_point = point('upt compressibility system','',6,6); END_TYPE; TYPE ndt_undersaturated_fvf_curve = volume('','upt beta factor system',6); END_TYPE; TYPE ndt_undersaturated_fvf_point = point('upt beta factor system','',6,6); END_TYPE; TYPE ndt_undersaturated_pressure_curve = volume('','upt system',6); END_TYPE; TYPE ndt_undersaturated_pressure_point = point('upt system','undersaturated fluid properties',6,6); END_TYPE; TYPE ndt_undersaturated_viscosity_curve = volume('','upt viscosity system',6); END_TYPE; TYPE ndt_undersaturated_viscosity_point = point('upt viscosity system','',6,6); END_TYPE; TYPE ndt_unit_productivity_index = quantity('unit productivity index',6); END_TYPE; TYPE ndt_unstructured_grid_3d = unstructured_3d_topology; END_TYPE; TYPE ndt_user_unique_identifier = INTEGER; END_TYPE; TYPE ndt_velocity = quantity('velocity',6); END_TYPE; TYPE ndt_vertical_geometry_edge = line('grid','vertical system',6); END_TYPE; TYPE ndt_vertical_geometry_face = surface('grid','vertical system',6); END_TYPE; TYPE ndt_viscometer_rheology_result = sample('viscometer rheology result',6); END_TYPE; TYPE ndt_viscosity_dynamic = quantity('viscosity dynamic',6); END_TYPE; TYPE ndt_viscosity_kinematic = quantity('viscosity kinematic',6); END_TYPE; TYPE ndt_volume = quantity('volume',6); END_TYPE; TYPE ndt_volume_fraction = REAL(7); END_TYPE; TYPE ndt_volume_per_length = quantity('volume per length',6); END_TYPE; TYPE ndt_volume_per_mass = quantity('volume per mass',6); END_TYPE; TYPE ndt_volume_per_std_volume = quantity('volume per std volume',6); END_TYPE; TYPE ndt_volume_per_volume = quantity('volume per volume',6); END_TYPE; TYPE ndt_volume_representation = ENUMERATION OF ( GRID ); END_TYPE; TYPE ndt_volumetric_heat_transfr_coefficient = quantity('volumetric heat transfer coefficient',6); END_TYPE; TYPE ndt_volumetric_thermal_expansion = quantity('volumetric thermal expansion',6); END_TYPE; TYPE ndt_water_depth_array = element('grid','node','water depth',6); END_TYPE; TYPE ndt_wave_length = quantity('wave length',6); END_TYPE; TYPE ndt_wet_gas_density_curve = surface('','pt density wet gas system',6); END_TYPE; TYPE ndt_wet_gas_density_point = point('','',6,6); END_TYPE; TYPE ndt_wet_gas_pressure_curve = line('','pt system',6); END_TYPE; TYPE ndt_wet_gas_pressure_point = point('pt system','wet gas properties',6,6); END_TYPE; TYPE ndt_wet_gas_z_factor_curve = surface('','pt wet gas z factor system',6); END_TYPE; TYPE ndt_wet_gas_z_factor_point = point('pt wet gas z factor system','',6,6); END_TYPE; TYPE ndt_work_per_length = quantity('work per length',6); END_TYPE; TYPE ndt_yearmonthinterval = yearmonthinterval; END_TYPE; TYPE ndt_yield = quantity('yield',6); END_TYPE; END_SCHEMA;