WISDEM Input Variables

This table may be downloaded as a CSV file or JSON file

Table 2 WISDEM Input Variable List

Variable	Units	Description
financese.machine_rating	kW
financese.tcc_per_kW	USD/kW
financese.offset_tcc_per_kW	USD/kW
financese.bos_per_kW	USD/kW
financese.opex_per_kW	USD/kW/year
financese.plant_aep_in	kW*h
financese.turbine_aep	kW*h
financese.wake_loss_factor
financese.fixed_charge_rate
financese.electricity_price	USD/kW/h
financese.reserve_margin_price	USD/kW/year
financese.capacity_credit
financese.benchmark_price	USD/kW/h
financese.turbine_number	n/a
orbit.site_depth	m	Site depth.
orbit.site_distance	km	Distance from site to installation port.
orbit.site_distance_to_landfall	km	Distance from site to landfall for export cable.
orbit.interconnection_distance	km	Distance from landfall to interconnection.
orbit.site_mean_windspeed	m/s	Mean windspeed of the site.
orbit.plant_turbine_spacing		Turbine spacing in rotor diameters.
orbit.plant_row_spacing		Row spacing in rotor diameters. Not used in ring layouts.
orbit.plant_substation_distance	km	Distance from first turbine in string to substation.
orbit.turbine_rating	MW	Rated capacity of a turbine.
orbit.turbine_rated_windspeed	m/s	Rated windspeed of the turbine.
orbit.turbine_capex	USD/kW	Turbine CAPEX
orbit.hub_height	m	Turbine hub height.
orbit.turbine_rotor_diameter	m	Turbine rotor diameter.
orbit.tower_mass	t	mass of the total tower.
orbit.tower_length	m	Total length of the tower.
orbit.tower_deck_space	m**2	Deck space required to transport the tower. Defaults to 0 in order to not be a constraint on installation.
orbit.nacelle_mass	t	mass of the rotor nacelle assembly (RNA).
orbit.nacelle_deck_space	m**2	Deck space required to transport the rotor nacelle assembly (RNA). Defaults to 0 in order to not be a constraint on installation.
orbit.blade_mass	t	mass of an individual blade.
orbit.blade_deck_space	m**2	Deck space required to transport a blade. Defaults to 0 in order to not be a constraint on installation.
orbit.mooring_line_mass	kg	Total mass of a mooring line
orbit.mooring_line_diameter	m	Cross-sectional diameter of a mooring line
orbit.mooring_line_length	m	Unstretched mooring line length
orbit.anchor_mass	kg	Total mass of an anchor
orbit.mooring_line_cost	USD	Mooring line unit cost.
orbit.mooring_anchor_cost	USD	Mooring line unit cost.
orbit.port_cost_per_month	USD/mo	Monthly port costs.
orbit.takt_time	h	Substructure assembly cycle time when doing assembly at the port.
orbit.floating_substructure_cost	USD	Floating substructure unit cost.
orbit.monopile_length	m	Length of monopile (including pile).
orbit.monopile_diameter	m	Diameter of monopile.
orbit.monopile_mass	t	mass of an individual monopile.
orbit.monopile_cost	USD	Monopile unit cost.
orbit.jacket_length	m	Length/height of jacket (including pile/buckets).
orbit.jacket_mass	t	mass of an individual jacket.
orbit.jacket_cost	USD	Jacket unit cost.
orbit.jacket_r_foot	m	Radius of jacket legs at base from centeroid.
orbit.transition_piece_mass	t	mass of an individual transition piece.
orbit.transition_piece_deck_space	m**2	Deck space required to transport a transition piece. Defaults to 0 in order to not be a constraint on installation.
orbit.transition_piece_cost	USD	Transition piece unit cost.
orbit.construction_insurance	USD/kW	Cost for construction insurance
orbit.construction_financing	USD/kW	Cost for construction financing
orbit.contingency	USD/kW	Cost in case of contingency
orbit.site_auction_price	USD	Cost to secure site lease
orbit.site_assessment_cost	USD	Cost to execute site assessment
orbit.construction_plan_cost	USD	Cost to do construction planning
orbit.installation_plan_cost	USD	Cost to do construction planning
orbit.boem_review_cost	USD	Cost for additional review by U.S. Dept of Interior Bureau of Ocean Energy Management (BOEM)
orbit.commissioning_cost_kW	USD/kW	Commissioning cost.
orbit.decommissioning_cost_kW	USD/kW	Decommissioning cost.
orbit.wtiv	n/a	Vessel configuration to use for installation of foundations and turbines.
orbit.feeder	n/a	Vessel configuration to use for (optional) feeder barges.
orbit.num_feeders	n/a	Number of feeder barges to use for installation of foundations and turbines.
orbit.num_towing	n/a	Number of towing vessels to use for floating platforms that are assembled at port (with or without the turbine).
orbit.num_station_keeping	n/a	Number of station keeping or AHTS vessels that attach to floating platforms under tow-out.
orbit.oss_install_vessel	n/a	Vessel configuration to use for installation of offshore substations.
orbit.number_of_turbines	n/a	Number of turbines.
orbit.number_of_blades	n/a	Number of blades per turbine.
orbit.num_mooring_lines	n/a	Number of mooring lines per platform.
orbit.anchor_type	n/a	Number of mooring lines per platform.
orbit.num_assembly_lines	n/a	Number of assembly lines used when assembly occurs at the port.
orbit.num_port_cranes	n/a	Number of cranes used at the port to load feeders / WTIVS when assembly occurs on-site or assembly cranes when assembling at port.
outputs_2_screen.aep	GW*h
outputs_2_screen.blade_mass	kg
outputs_2_screen.lcoe	USD/MW/h
outputs_2_screen.My_std	N*m
outputs_2_screen.flp1_std	deg
outputs_2_screen.PC_omega	rad/s
outputs_2_screen.PC_zeta
outputs_2_screen.VS_omega	rad/s
outputs_2_screen.VS_zeta
outputs_2_screen.Flp_omega	rad/s
outputs_2_screen.Flp_zeta
outputs_2_screen.tip_deflection	m
wombat.years	year	Number of years to simulation the operations and maintenance phase of the farm lifecycle
wombat.equipment_dispatch_distance	km	Distance, in km, that servicing equipment must travel daily to reach the wind farm
wombat.repair_port_distance	km	Distance, in km, that tugboats must travel to reach the wind farm for tow-to-port repairs
wombat.reduced_speed	km/h	Reduced speed applied to servicing equipment in the reduced speed period
wombat.project_capacity	MW	Total wind farm capacity
wombat.turbine_capex_kw	USD/kW	Turbine CapEx per kW of nameplate capacity
wombat.turbine_capacity	W	Turbine nameplate capacity
wombat.power_converter_minor_repair_scale	unitless	1 / mean time between failure (years)
wombat.power_converter_minor_repair_time	h	Number of hours to complete the repair
wombat.power_converter_minor_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.power_converter_major_repair_scale	unitless	1 / mean time between failure (years)
wombat.power_converter_major_repair_time	h	Number of hours to complete the repair
wombat.power_converter_major_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.power_converter_replacement_scale	unitless	1 / mean time between failure (years)
wombat.power_converter_replacement_time	h	Number of hours to complete the repair
wombat.power_converter_replacement_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.electrical_system_minor_repair_scale	unitless	1 / mean time between failure (years)
wombat.electrical_system_minor_repair_time	h	Number of hours to complete the repair
wombat.electrical_system_minor_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.electrical_system_major_repair_scale	unitless	1 / mean time between failure (years)
wombat.electrical_system_major_repair_time	h	Number of hours to complete the repair
wombat.electrical_system_major_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.electrical_system_replacement_scale	unitless	1 / mean time between failure (years)
wombat.electrical_system_replacement_time	h	Number of hours to complete the repair
wombat.electrical_system_replacement_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.hydraulic_pitch_system_minor_repair_scale	unitless	1 / mean time between failure (years)
wombat.hydraulic_pitch_system_minor_repair_time	h	Number of hours to complete the repair
wombat.hydraulic_pitch_system_minor_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.hydraulic_pitch_system_major_repair_scale	unitless	1 / mean time between failure (years)
wombat.hydraulic_pitch_system_major_repair_time	h	Number of hours to complete the repair
wombat.hydraulic_pitch_system_major_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.hydraulic_pitch_system_replacement_scale	unitless	1 / mean time between failure (years)
wombat.hydraulic_pitch_system_replacement_time	h	Number of hours to complete the repair
wombat.hydraulic_pitch_system_replacement_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.ballast_pump_minor_repair_scale	unitless	1 / mean time between failure (years)
wombat.ballast_pump_minor_repair_time	h	Number of hours to complete the repair
wombat.ballast_pump_minor_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.yaw_system_minor_repair_scale	unitless	1 / mean time between failure (years)
wombat.yaw_system_minor_repair_time	h	Number of hours to complete the repair
wombat.yaw_system_minor_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.yaw_system_major_repair_scale	unitless	1 / mean time between failure (years)
wombat.yaw_system_major_repair_time	h	Number of hours to complete the repair
wombat.yaw_system_major_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.yaw_system_replacement_scale	unitless	1 / mean time between failure (years)
wombat.yaw_system_replacement_time	h	Number of hours to complete the repair
wombat.yaw_system_replacement_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.rotor_blades_minor_repair_scale	unitless	1 / mean time between failure (years)
wombat.rotor_blades_minor_repair_time	h	Number of hours to complete the repair
wombat.rotor_blades_minor_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.rotor_blades_major_repair_scale	unitless	1 / mean time between failure (years)
wombat.rotor_blades_major_repair_time	h	Number of hours to complete the repair
wombat.rotor_blades_major_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.rotor_blades_replacement_scale	unitless	1 / mean time between failure (years)
wombat.rotor_blades_replacement_time	h	Number of hours to complete the repair
wombat.rotor_blades_replacement_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.generator_minor_repair_scale	unitless	1 / mean time between failure (years)
wombat.generator_minor_repair_time	h	Number of hours to complete the repair
wombat.generator_minor_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.generator_major_repair_scale	unitless	1 / mean time between failure (years)
wombat.generator_major_repair_time	h	Number of hours to complete the repair
wombat.generator_major_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.generator_replacement_scale	unitless	1 / mean time between failure (years)
wombat.generator_replacement_time	h	Number of hours to complete the repair
wombat.generator_replacement_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.drive_train_minor_repair_scale	unitless	1 / mean time between failure (years)
wombat.drive_train_minor_repair_time	h	Number of hours to complete the repair
wombat.drive_train_minor_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.drive_train_major_repair_scale	unitless	1 / mean time between failure (years)
wombat.drive_train_major_repair_time	h	Number of hours to complete the repair
wombat.drive_train_major_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.drive_train_replacement_scale	unitless	1 / mean time between failure (years)
wombat.drive_train_replacement_time	h	Number of hours to complete the repair
wombat.drive_train_replacement_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.anchor_minor_repair_scale	unitless	1 / mean time between failure (years)
wombat.anchor_minor_repair_time	h	Number of hours to complete the repair
wombat.anchor_minor_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.anchor_major_repair_scale	unitless	1 / mean time between failure (years)
wombat.anchor_major_repair_time	h	Number of hours to complete the repair
wombat.anchor_major_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.anchor_replacement_scale	unitless	1 / mean time between failure (years)
wombat.anchor_replacement_time	h	Number of hours to complete the repair
wombat.anchor_replacement_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.mooring_lines_minor_repair_scale	unitless	1 / mean time between failure (years)
wombat.mooring_lines_minor_repair_time	h	Number of hours to complete the repair
wombat.mooring_lines_minor_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.mooring_lines_major_repair_scale	unitless	1 / mean time between failure (years)
wombat.mooring_lines_major_repair_time	h	Number of hours to complete the repair
wombat.mooring_lines_major_repair_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.mooring_lines_replacement_scale	unitless	1 / mean time between failure (years)
wombat.mooring_lines_replacement_time	h	Number of hours to complete the repair
wombat.mooring_lines_replacement_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.mooring_lines_buoyancy_module_replacement_scale	unitless	1 / mean time between failure (years)
wombat.mooring_lines_buoyancy_module_replacement_time	h	Number of hours to complete the repair
wombat.mooring_lines_buoyancy_module_replacement_materials	USD	Total cost of materials used to complete the repair. If between 0 and 1, the cost is proportional to the turbine CapEx.
wombat.workday_start	n/a	Hour of the day where any work-related activities begin
wombat.workday_end	n/a	Hour of the day where any work-related activities end
wombat.n_ctv	n/a	Number of crew transfer vessels (offshore) or onsite trucks (land-based) that should be made available to the wind farm.
wombat.n_hlv	n/a	Number of heavy lift vessels (fixed-bottom offshore) or crawler cranes (land-based) that should be made available to the wind farm (fixed-bottom simulations only)
wombat.n_tugboat	n/a	Number of tugboat groups that should be available to the port to tow floating turbines to port and back
wombat.port_workday_start	n/a	Hour of the day where any work-related activities begin for port-side repairs
wombat.port_workday_end	n/a	Hour of the day where any work-related activities end for port-side repairs
wombat.n_port_crews	n/a	Number of port-side crews available to work on simultaneous repairs for any at-port turbine
wombat.max_port_operations	n/a	Number of turbines that can be at port at once
wombat.maintenance_start	n/a	Date of first maintenance event to determine regular interval timing. Can be set to prior to the starting year to ensure staggered starts.
wombat.non_operational_start	n/a	Starting date, in MM/DD format, for an annual period where the site is inaccessible
wombat.non_operational_end	n/a	Ending date, in MM/DD format, for an annual period where the site is inaccessible
wombat.reduced_speed_start	n/a	Starting date, in MM/DD format, for an annual period where traveling speed is reduced
wombat.reduced_speed_end	n/a	Ending date, in MM/DD format, for an annual period where traveling speed is reduced
wombat.random_seed	n/a	Random seed for the internal random generator
wombat.layout	n/a	Tabular wind farm layout generated from ORBIT
fixedse.env.distLoads.windLoads_Px	N/m
fixedse.env.distLoads.windLoads_Py	N/m
fixedse.env.distLoads.windLoads_Pz	N/m
fixedse.env.distLoads.windLoads_qdyn	N/m**2
fixedse.env.distLoads.windLoads_z	m
fixedse.env.distLoads.windLoads_beta	deg
fixedse.env.distLoads.waveLoads_Px	N/m
fixedse.env.distLoads.waveLoads_Py	N/m
fixedse.env.distLoads.waveLoads_Pz	N/m
fixedse.env.distLoads.waveLoads_qdyn	N/m**2
fixedse.env.distLoads.waveLoads_z	m
fixedse.env.distLoads.waveLoads_beta	deg
fixedse.z_global	m
fixedse.yaw	deg
fixedse.rho_water	kg/m**3
fixedse.z0	m
fixedse.water_depth	m
fixedse.Uc	m/s	mean current speed
fixedse.Hsig_wave	m
fixedse.Tsig_wave	s
fixedse.env.waveLoads.U	m/s
fixedse.env.waveLoads.A	m/s**2
fixedse.env.waveLoads.p	N/m**2
fixedse.outer_diameter_full	m
fixedse.beta_wave	deg
fixedse.mu_water	kg/m/s
fixedse.ca_usr
fixedse.cd_usr
fixedse.env.Uref	m/s
fixedse.wind_reference_height	m
fixedse.shearExp
fixedse.env.windLoads.U	m/s
fixedse.beta_wind	deg
fixedse.rho_air	kg/m**3
fixedse.mu_air	kg/m/s
fixedse.joint1	m
fixedse.joint2	m
fixedse.s_full	m
fixedse.s_all
fixedse.g2e.Px_global	N/m
fixedse.g2e.Py_global	N/m
fixedse.g2e.Pz_global	N/m
fixedse.g2e.qdyn_global	Pa
fixedse.lc:Px	N/m
fixedse.lc:Py	N/m
fixedse.lc:Pz	N/m
fixedse.lc:qdyn	Pa
fixedse.monopile.z_soil	N/m
fixedse.monopile.k_soil	N/m
fixedse.nodes_xyz	m
fixedse.section_A	m**2
fixedse.section_Asx	m**2
fixedse.section_Asy	m**2
fixedse.section_Ixx	kg*m**2
fixedse.section_Iyy	kg*m**2
fixedse.section_J0	kg*m**2
fixedse.section_rho	kg/m**3
fixedse.section_E	Pa
fixedse.section_G	Pa
fixedse.t_full	m
fixedse.sigma_y_full	Pa
fixedse.qdyn	Pa
fixedse.bending_height	m
fixedse.tower_xyz	m
fixedse.tower_A	m**2
fixedse.tower_Asx	m**2
fixedse.tower_Asy	m**2
fixedse.tower_Ixx	kg*m**2
fixedse.tower_Iyy	kg*m**2
fixedse.tower_J0	kg*m**2
fixedse.tower_rho	kg/m**3
fixedse.tower_E	Pa
fixedse.tower_G	Pa
fixedse.tower_outer_diameter_full	m
fixedse.tower_t_full	m
fixedse.tower_sigma_y_full	Pa
fixedse.tower_qdyn	Pa
fixedse.tower_bending_height	m
fixedse.monopile.rna_F	N
fixedse.monopile.rna_M	N*m
fixedse.turbine_F	N
fixedse.turbine_M	N*m
fixedse.transition_piece_mass	kg
fixedse.transition_piece_I	kg*m**2
fixedse.gravity_foundation_mass	kg
fixedse.gravity_foundation_I	kg*m**2
fixedse.transition_piece_height	m
fixedse.suctionpile_depth	m
fixedse.turbine_mass	kg
fixedse.turbine_cg	m
fixedse.turbine_I	kg*m**2
fixedse.rna_mass	kg
fixedse.rna_I	kg*m**2
fixedse.rna_cg	m
fixedse.Px	N/m
fixedse.Py	N/m
fixedse.Pz	N/m
fixedse.tower_Px	N/m
fixedse.tower_Py	N/m
fixedse.tower_Pz	N/m
fixedse.z_full	m
fixedse.E_full	Pa
fixedse.G_full	Pa
fixedse.rho_full	kg/m**3
fixedse.post.section_L	m
fixedse.post.cylinder_Fz	N
fixedse.post.cylinder_Vx	N
fixedse.post.cylinder_Vy	N
fixedse.post.cylinder_Mxx	N*m
fixedse.post.cylinder_Myy	N*m
fixedse.post.cylinder_Mzz	N*m
fixedse.post_monopile_tower.z_full	m
fixedse.post_monopile_tower.outer_diameter_full	m
fixedse.post_monopile_tower.t_full	m
fixedse.post_monopile_tower.bending_height	m
fixedse.post_monopile_tower.E_full	Pa
fixedse.post_monopile_tower.G_full	Pa
fixedse.post_monopile_tower.rho_full	kg/m**3
fixedse.post_monopile_tower.sigma_y_full	Pa
fixedse.post_monopile_tower.section_A	m**2
fixedse.post_monopile_tower.section_Asx	m**2
fixedse.post_monopile_tower.section_Asy	m**2
fixedse.post_monopile_tower.section_Ixx	kg*m**2
fixedse.post_monopile_tower.section_Iyy	kg*m**2
fixedse.post_monopile_tower.section_J0	kg*m**2
fixedse.post_monopile_tower.section_rho	kg/m**3
fixedse.post_monopile_tower.section_E	Pa
fixedse.post_monopile_tower.section_G	Pa
fixedse.post_monopile_tower.section_L	m
fixedse.post_monopile_tower.cylinder_Fz	N
fixedse.post_monopile_tower.cylinder_Vx	N
fixedse.post_monopile_tower.cylinder_Vy	N
fixedse.post_monopile_tower.cylinder_Mxx	N*m
fixedse.post_monopile_tower.cylinder_Myy	N*m
fixedse.post_monopile_tower.cylinder_Mzz	N*m
fixedse.post_monopile_tower.qdyn	Pa
tcc.main_bearing_mass	kg
tcc.bearing_mass_cost_coeff	USD/kg
tcc.bedplate_mass	kg
tcc.bedplate_mass_cost_coeff	USD/kg
tcc.blade_mass	kg
tcc.blade_mass_cost_coeff	USD/kg
tcc.blade_cost_external	USD
tcc.brake_mass	kg
tcc.brake_mass_cost_coeff	USD/kg
tcc.machine_rating	kW
tcc.controls_machine_rating_cost_coeff	USD/kW
tcc.converter_mass	kg
tcc.converter_mass_cost_coeff	USD/kg
tcc.cover_mass	kg
tcc.cover_mass_cost_coeff	USD/kg
tcc.elec_connec_machine_rating_cost_coeff	USD/kW
tcc.gearbox_mass	kg
tcc.gearbox_torque_density	N*m/kg	In 2024, modern 5-7MW gearboxes are able to reach 200 Nm/kg
tcc.gearbox_torque_cost	USD/kN/m	In 2024, modern 5-7MW gearboxes cost approx $50/kNm
tcc.generator_mass	kg
tcc.generator_mass_cost_coeff	USD/kg
tcc.generator_cost_external	USD
tcc.hss_mass	kg
tcc.hss_mass_cost_coeff	USD/kg
tcc.hub_cost	USD
tcc.hub_mass	kg
tcc.pitch_system_cost	USD
tcc.pitch_system_mass	kg
tcc.spinner_cost	USD
tcc.spinner_mass	kg
tcc.hub_assemblyCostMultiplier
tcc.hub_overheadCostMultiplier
tcc.hub_profitMultiplier
tcc.hub_transportMultiplier
tcc.hub_mass_cost_coeff	USD/kg
tcc.hvac_mass	kg
tcc.hvac_mass_cost_coeff	USD/kg
tcc.lss_mass	kg
tcc.lss_mass_cost_coeff	USD/kg
tcc.lss_cost	USD
tcc.main_bearing_cost	USD
tcc.gearbox_cost	USD
tcc.hss_cost	USD
tcc.brake_cost	USD
tcc.generator_cost	USD
tcc.bedplate_cost	USD
tcc.yaw_system_cost	USD
tcc.yaw_mass	kg
tcc.converter_cost	USD
tcc.hvac_cost	USD
tcc.cover_cost	USD
tcc.elec_cost	USD
tcc.controls_cost	USD
tcc.platforms_mass	kg
tcc.platforms_cost	USD
tcc.transformer_cost	USD
tcc.transformer_mass	kg
tcc.nacelle_assemblyCostMultiplier
tcc.nacelle_overheadCostMultiplier
tcc.nacelle_profitMultiplier
tcc.nacelle_transportMultiplier
tcc.main_bearing_number	n/a
tcc.blade_cost	USD
tcc.rotor_cost	USD
tcc.rotor_mass_tcc	kg
tcc.nacelle_cost	USD
tcc.nacelle_mass_tcc	kg
tcc.tower_cost	USD
tcc.tower_mass	kg
tcc.turbine_cost	USD
tcc.turbine_cost_kW	USD/kW
tcc.turbine_mass_tcc	kg
tcc.pitch_system_mass_cost_coeff	USD/kg
tcc.platforms_mass_cost_coeff	USD/kg
tcc.crane_cost	USD
tcc.crane	n/a
tcc.hub_system_cost	USD
tcc.hub_system_mass_tcc	kg
tcc.blade_number	n/a
tcc.spinner_mass_cost_coeff	USD/kg
tcc.tower_parts_cost	USD
tcc.tower_assemblyCostMultiplier
tcc.tower_overheadCostMultiplier
tcc.tower_profitMultiplier
tcc.tower_transportMultiplier
tcc.tower_mass_cost_coeff	USD/kg
tcc.tower_cost_external	USD
tcc.transformer_mass_cost_coeff	USD/kg
tcc.turbine_assemblyCostMultiplier
tcc.turbine_overheadCostMultiplier
tcc.turbine_profitMultiplier
tcc.turbine_transportMultiplier
tcc.yaw_mass_cost_coeff	USD/kg
tcons.rated_Omega	rpm	rotor rotation speed at rated
tcons.tower_freq	Hz
tcons.blade_number	n/a
tcons.tip_deflection	m
tcons.Rtip	m
tcons.ref_axis_blade	m
tcons.precone	deg
tcons.tilt	deg
tcons.overhang	m
tcons.ref_axis_tower	m
tcons.outer_diameter_full	m
tcons.max_allowable_td_ratio
tcons.rotor_orientation	n/a
towerse.env.distLoads.windLoads_Px	N/m
towerse.env.distLoads.windLoads_Py	N/m
towerse.env.distLoads.windLoads_Pz	N/m
towerse.env.distLoads.windLoads_qdyn	N/m**2
towerse.env.distLoads.windLoads_z	m
towerse.env.distLoads.windLoads_beta	deg
towerse.env.distLoads.waveLoads_Px	N/m
towerse.env.distLoads.waveLoads_Py	N/m
towerse.env.distLoads.waveLoads_Pz	N/m
towerse.env.distLoads.waveLoads_qdyn	N/m**2
towerse.env.distLoads.waveLoads_z	m
towerse.env.distLoads.waveLoads_beta	deg
towerse.z_global	m
towerse.yaw	deg
towerse.env.Uref	m/s
towerse.wind_reference_height	m
towerse.z0	m
towerse.shearExp
towerse.env.windLoads.U	m/s
towerse.outer_diameter_full	m
towerse.beta_wind	deg
towerse.rho_air	kg/m**3
towerse.mu_air	kg/m/s
towerse.cd_usr
towerse.joint1	m
towerse.joint2	m
towerse.s_full	m
towerse.s_all
towerse.g2e.Px_global	N/m
towerse.g2e.Py_global	N/m
towerse.g2e.Pz_global	N/m
towerse.g2e.qdyn_global	Pa
towerse.lc:Px	N/m
towerse.lc:Py	N/m
towerse.lc:Pz	N/m
towerse.lc:qdyn	Pa
towerse.z_full	m
towerse.t_full	m
towerse.tower_height	m
towerse.E_full	Pa
towerse.G_full	Pa
towerse.rho_full	kg/m**3
towerse.sigma_y_full	Pa
towerse.section_A	m**2
towerse.section_Asx	m**2
towerse.section_Asy	m**2
towerse.section_Ixx	kg*m**2
towerse.section_Iyy	kg*m**2
towerse.section_J0	kg*m**2
towerse.section_rho	kg/m**3
towerse.section_E	Pa
towerse.section_G	Pa
towerse.section_L	m
towerse.post.cylinder_Fz	N
towerse.post.cylinder_Vx	N
towerse.post.cylinder_Vy	N
towerse.post.cylinder_Mxx	N*m
towerse.post.cylinder_Myy	N*m
towerse.post.cylinder_Mzz	N*m
towerse.qdyn	Pa
towerse.nodes_xyz	m
towerse.lumped_mass	kg
towerse.rna_mass	kg
towerse.rna_I	kg*m**2
towerse.rna_cg	m
towerse.tower.rna_F	N
towerse.tower.rna_M	N*m
towerse.Px	N/m
towerse.Py	N/m
towerse.Pz	N/m
towerse.tower_mass	kg
towerse.tower_center_of_mass	m
towerse.tower_I_base	kg*m**2
fixedse.member.gc.d	m
fixedse.member.gc.t	m
fixedse.member.s
fixedse.member.height	m
fixedse.monopile_outer_diameter	m
fixedse.member.ca_usr_grid
fixedse.member.cd_usr_grid
fixedse.monopile_wall_thickness	m
fixedse.member.E	Pa
fixedse.member.G	Pa
fixedse.member.sigma_y	Pa
fixedse.member.rho	kg/m**3
fixedse.member.unit_cost	USD/kg
fixedse.member.outfitting_factor
fixedse.member.s_ghost1
fixedse.member.s_ghost2
fixedse.monopile_s
fixedse.s_const1
fixedse.s_const2
fixedse.monopile_layer_thickness	m
fixedse.monopile_outer_diameter_in	m
fixedse.E_mat	Pa
fixedse.E_user	Pa
fixedse.G_mat	Pa
fixedse.sigma_y_mat	Pa
fixedse.sigma_ult_mat	Pa
fixedse.wohler_exp_mat
fixedse.wohler_A_mat
fixedse.rho_mat	kg/m**3
fixedse.unit_cost_mat	USD/kg
fixedse.outfitting_factor_in
fixedse.monopile_layer_materials	n/a
fixedse.member.ballast_materials	n/a
fixedse.material_names	n/a
fixedse.outfitting_full
fixedse.member.unit_cost_full	USD/kg
fixedse.labor_cost_rate	USD/min
fixedse.painting_cost_rate	USD/m**2
fixedse.monopile_mass_user	kg
fixedse.mono.cylinder_mass	kg
fixedse.mono.cylinder_cost	USD
fixedse.mono.cylinder_z_cg	m
fixedse.mono.cylinder_I_base	kg*m**2
fixedse.transition_piece_cost	USD
fixedse.tower_mass	kg
fixedse.tower_cost	USD
fixedse.monopile_height	m
fixedse.tower_foundation_height	m
fixedse.monopile_foundation_height	m
fixedse.tower_base_diameter	m
fixedse.monopile_top_diameter	m
fixedse.soil.d0	m
fixedse.G_soil	Pa
fixedse.nu_soil
fixedse.soil.k_usr	N/m
rotorse.ccblade.Uhub	m/s	Undisturbed wind speed
rotorse.tsr		Tip speed ratio
rotorse.pitch	deg	Pitch angle
rotorse.r	m	radial locations where blade is defined (should be increasing and not go all the way to hub or tip)
rotorse.ccblade.s_opt_chord		1D array of the non-dimensional spanwise grid defined along blade axis to optimize the blade chord
rotorse.ccblade.s_opt_theta		1D array of the non-dimensional spanwise grid defined along blade axis to optimize the blade twist
rotorse.chord	m	chord length at each section
rotorse.ccblade.theta_in	rad	twist angle at each section (positive decreases angle of attack)
rotorse.ccblade.aoa_op	rad	1D array with the operational angles of attack for the airfoils along blade span.
rotorse.airfoils_aoa	deg	angle of attack grid for polars
rotorse.airfoils_cl		lift coefficients, spanwise
rotorse.airfoils_cd		drag coefficients, spanwise
rotorse.airfoils_cm		moment coefficients, spanwise
rotorse.airfoils_Re		Reynolds numbers of polars
rotorse.Rhub	m	hub radius
rotorse.Rtip	m	Distance between rotor center and blade tip along z axis of blade root c.s.
rotorse.ccblade.rthick		1D array of the relative thicknesses of the blade defined along span.
rotorse.precurve	m	precurve at each section
rotorse.precurveTip	m	precurve at tip
rotorse.presweep	m	presweep at each section
rotorse.presweepTip	m	presweep at tip
rotorse.hub_height	m	hub height
rotorse.precone	deg	precone angle
rotorse.tilt	deg	shaft tilt
rotorse.yaw	deg	yaw error
rotorse.rho_air	kg/m**3	density of air
rotorse.mu_air	kg/m/s	dynamic viscosity of air
rotorse.shearExp		shear exponent
rotorse.nBlades	n/a	number of blades
rotorse.nSector	n/a	number of sectors to divide rotor face into in computing thrust and power
rotorse.tiploss	n/a	include Prandtl tip loss model
rotorse.hubloss	n/a	include Prandtl hub loss model
rotorse.wakerotation	n/a	include effect of wake rotation (i.e., tangential induction factor is nonzero)
rotorse.usecd	n/a	use drag coefficient in computing induction factors
rotorse.rc.blade_length	m	blade length
rotorse.rc.s		blade nondimensional span location
rotorse.rc.chord	m	Chord distribution
rotorse.rc.coord_xy_interp		3D array of the non-dimensional x and y airfoil coordinates of the airfoils interpolated along span for n_span stations.
rotorse.rc.web_start_nd		2D array of the non-dimensional start point defined along the outer profile of a web. The TE suction side is 0, the TE pressure side is 1. The first dimension represents each web, the second dimension represents each entry along blade span.
rotorse.rc.web_end_nd		2D array of the non-dimensional end point defined along the outer profile of a web. The TE suction side is 0, the TE pressure side is 1. The first dimension represents each web, the second dimension represents each entry along blade span.
rotorse.rc.layer_thickness	m	2D array of the thickness of the layers of the blade structure. The first dimension represents each layer, the second dimension represents each entry along blade span.
rotorse.rc.layer_start_nd		2D array of the non-dimensional start point defined along the outer profile of a layer. The TE suction side is 0, the TE pressure side is 1. The first dimension represents each layer, the second dimension represents each entry along blade span.
rotorse.rc.layer_end_nd		2D array of the non-dimensional end point defined along the outer profile of a layer. The TE suction side is 0, the TE pressure side is 1. The first dimension represents each layer, the second dimension represents each entry along blade span.
rotorse.rc.rho	kg/m**3	1D array of the density of the materials. For composites, this is the density of the laminate.
rotorse.rc.unit_cost	USD/kg	1D array of the unit costs of the materials.
rotorse.rc.waste		1D array of the non-dimensional waste fraction of the materials.
rotorse.rc.rho_fiber	kg/m**3	1D array of the density of the fibers of the materials.
rotorse.rc.ply_t	m	1D array of the ply thicknesses of the materials. Non-composite materials are kept at 0.
rotorse.rc.fwf		1D array of the non-dimensional fiber weight fraction of the composite materials. Non-composite materials are kept at 0.
rotorse.rc.fvf		1D array of the non-dimensional fiber volume fraction of the composite materials. Non-composite materials are kept at 0.
rotorse.rc.roll_mass	kg	1D array of the roll mass of the composite fabrics. Non-composite materials are kept at 0.
rotorse.rc.flange_adhesive_squeezed		Extra width of the adhesive once squeezed
rotorse.rc.flange_thick	m	Average thickness of adhesive
rotorse.rc.flange_width	m	Average width of adhesive lines
rotorse.rc.t_bolt_unit_cost	USD	Cost of one t-bolt
rotorse.rc.t_bolt_unit_mass	kg	Mass of one t-bolt
rotorse.rc.t_bolt_spacing	m	Spacing of t-bolts along blade root circumference
rotorse.rc.barrel_nut_unit_cost	USD	Cost of one barrel nut
rotorse.rc.barrel_nut_unit_mass	kg	Mass of one barrel nut
rotorse.rc.LPS_unit_mass	kg/m	Unit mass of the lightining protection system. Linear scaling based on the weight of 150 lbs for the 61.5 m NREL 5MW blade
rotorse.rc.LPS_unit_cost	USD/m	Unit cost of the lightining protection system. Linear scaling based on the cost of 2500$ for the 61.5 m NREL 5MW blade
rotorse.rc.root_preform_length		Percentage of blade length starting from blade root that is preformed and later inserted into the mold
rotorse.rc.build_layer	n/a	1D array of boolean values indicating how to build a layer.
rotorse.rc.mat_name	n/a	1D array of names of materials.
rotorse.rc.orth	n/a	1D array of flags to set whether a material is isotropic (0) or orthtropic (1). Each entry represents a material.
rotorse.EA	N	Axial stiffness at the elastic center, using the convention of WISDEM solver PreComp.
rotorse.EIxx	N*m**2	Section lag (edgewise) bending stiffness about the XE axis, using the convention of WISDEM solver PreComp.
rotorse.EIyy	N*m**2	Section flap bending stiffness about the YE axis, using the convention of WISDEM solver PreComp.
rotorse.EIxy	N*m**2	Coupled flap-lag stiffness with respect to the XE-YE frame, using the convention of WISDEM solver PreComp.
rotorse.re.EA_EIxx	N*m	Coupled axial-lag stiffness with respect to the XE-YE frame, using the convention of WISDEM solver PreComp.
rotorse.re.EA_EIyy	N*m	Coupled axial-flap stiffness with respect to the XE-YE frame, using the convention of WISDEM solver PreComp.
rotorse.re.EIxx_GJ	N*m**2	Coupled lag-torsion stiffness with respect to the XE-YE frame, using the convention of WISDEM solver PreComp.
rotorse.re.EIyy_GJ	N*m**2	Coupled flap-torsion stiffness with respect to the XE-YE frame, using the convention of WISDEM solver PreComp.
rotorse.re.EA_GJ	N*m	Coupled axial-torsion stiffness with respect to the XE-YE frame, using the convention of WISDEM solver PreComp.
rotorse.GJ	N*m**2	Section torsion stiffness at the elastic center, using the convention of WISDEM solver PreComp.
rotorse.rhoA	kg/m	Section mass per unit length, using the convention of WISDEM solver PreComp.
rotorse.rhoJ	kg*m	polar mass moment of inertia per unit length, using the convention of WISDEM solver PreComp.
rotorse.re.Tw_iner	deg	Orientation of the section principal inertia axes with respect the blade reference plane, using the convention of WISDEM solver PreComp.
rotorse.re.x_tc	m	X-coordinate of the tension-center offset with respect to the XR-YR axes, using the convention of WISDEM solver PreComp.
rotorse.re.y_tc	m	Chordwise offset of the section tension-center with respect to the XR-YR axes, using the convention of WISDEM solver PreComp.
rotorse.re.x_cg	m	X-coordinate of the center-of-mass offset with respect to the XR-YR axes, using the convention of WISDEM solver PreComp.
rotorse.re.y_cg	m	Chordwise offset of the section center of mass with respect to the XR-YR axes, using the convention of WISDEM solver PreComp.
rotorse.re.flap_iner	kg/m	Section flap inertia about the Y_G axis per unit length, using the convention of WISDEM solver PreComp.
rotorse.re.edge_iner	kg/m	Section lag inertia about the X_G axis per unit length, using the convention of WISDEM solver PreComp.
rotorse.re.generate_KI.theta	deg	Aerodynamic twist angle at each section (positive decreases angle of attack)
rotorse.theta	deg	Twist angle at each section (positive decreases angle of attack)
rotorse.re.section_offset_y	m	1D array of the airfoil position relative to the reference axis, specifying the distance in meters along the chordline from the reference axis to the leading edge. 0 means that the airfoil is pinned at the leading edge, a positive offset means that the leading edge is upstream of the reference axis in local chordline coordinates, and a negative offset that the leading edge aft of the reference axis.
rotorse.re.coord_xy_interp		3D array of the non-dimensional x and y airfoil coordinates of the airfoils interpolated along span for n_span stations.
rotorse.re.precomp.uptilt	deg	Nacelle uptilt angle. A standard machine has positive values.
rotorse.re.precomp.web_start_nd		2D array of the non-dimensional start point defined along the outer profile of a web. The TE suction side is 0, the TE pressure side is 1. The first dimension represents each entry along blade span, the second dimension represents each web.
rotorse.re.precomp.web_end_nd		2D array of the non-dimensional end point defined along the outer profile of a web. The TE suction side is 0, the TE pressure side is 1. The first dimension represents each entry along blade span, the second dimension represents each web.
rotorse.re.precomp.layer_thickness	m	2D array of the thickness of the layers of the blade structure. The first dimension represents each entry along blade span, the second dimension represents each layer.
rotorse.re.precomp.layer_start_nd		2D array of the start_nd_arc of the anchors. The first dimension represents each entry along blade span, the second dimension represents each layer.
rotorse.re.precomp.layer_end_nd		2D array of the end_nd_arc of the anchors. The first dimension represents each entry along blade span, the second dimension represents each layer.
rotorse.re.precomp.fiber_orientation	deg	2D array of the orientation of the layers of the blade structure. The first dimension represents each entry along blade span, the second dimension represents each layer.
rotorse.re.precomp.E	Pa	2D array of the Youngs moduli of the materials. Each row represents a material, the three columns represent E11, E22 and E33.
rotorse.re.precomp.G	Pa	2D array of the shear moduli of the materials. Each row represents a material, the three columns represent G12, G13 and G23.
rotorse.re.precomp.nu		2D array of the Poisson ratio of the materials. Each row represents a material, the three columns represent nu12, nu13 and nu23.
rotorse.re.precomp.rho	kg/m**3	1D array of the density of the materials. For composites, this is the density of the laminate.
rotorse.re.precomp.joint_position		Spanwise position of the segmentation joint.
rotorse.re.precomp.joint_mass	kg	Mass of the joint.
rotorse.re.n_blades	n/a	Number of blades of the rotor.
rotorse.re.precomp.build_layer	n/a	1D array of boolean values indicating how to build a layer.
rotorse.re.precomp.mat_name	n/a	1D array of names of materials.
rotorse.re.precomp.orth	n/a	1D array of flags to set whether a material is isotropic (0) or orthtropic (1). Each entry represents a material.
rotorse.total_bc.joint_cost	USD	Total blade joint cost
rotorse.total_bc.inner_blade_cost	USD	Total cost (variable and fixed) for the blade inner portion.
rotorse.total_bc.outer_blade_cost	USD	Total cost (variable and fixed) for the blade outer portion.
rotorse.wt_class.V_mean_overwrite
rotorse.wt_class.V_extreme50_overwrite
rotorse.wt_class.turbine_class	n/a
towerse.distribute_lumped_mass.mass_den	kg/m
towerse.distribute_lumped_mass.section_height	m
towerse.lumped_mass_in	kg
towerse.member.gc.d	m
towerse.member.gc.t	m
towerse.member.s
towerse.member.height	m
towerse.tower_outer_diameter	m
towerse.member.ca_usr_grid
towerse.member.cd_usr_grid
towerse.tower_wall_thickness	m
towerse.member.E	Pa
towerse.member.G	Pa
towerse.member.sigma_y	Pa
towerse.member.rho	kg/m**3
towerse.member.unit_cost	USD/kg
towerse.member.outfitting_factor
towerse.rho_water	kg/m**3
towerse.member.s_ghost1
towerse.member.s_ghost2
towerse.tower_s
towerse.member.s_const1
towerse.member.s_const2
towerse.tower_layer_thickness	m
towerse.tower_outer_diameter_in	m
towerse.E_mat	Pa
towerse.E_user	Pa
towerse.G_mat	Pa
towerse.sigma_y_mat	Pa
towerse.sigma_ult_mat	Pa
towerse.wohler_exp_mat
towerse.wohler_A_mat
towerse.rho_mat	kg/m**3
towerse.unit_cost_mat	USD/kg
towerse.outfitting_factor_in
towerse.tower_layer_materials	n/a
towerse.member.ballast_materials	n/a
towerse.material_names	n/a
towerse.outfitting_full
towerse.member.unit_cost_full	USD/kg
towerse.labor_cost_rate	USD/min
towerse.painting_cost_rate	USD/m**2
towerse.tower_mass_user	kg
towerse.hub_height	m
towerse.foundation_height	m
af_3d.aoa	deg	1D array of the angles of attack used to define the polars of the airfoils. All airfoils defined in openmdao share this grid.
af_3d.Re		1D array of the Reynolds numbers used to define the polars of the airfoils. All airfoils defined in openmdao share this grid.
af_3d.cl		4D array with the lift coefficients of the airfoils. Dimension 0 is along the blade span for n_span stations, dimension 1 is along the angles of attack, dimension 2 is along the Reynolds number.
af_3d.cd		4D array with the drag coefficients of the airfoils. Dimension 0 is along the blade span for n_span stations, dimension 1 is along the angles of attack, dimension 2 is along the Reynolds number.
af_3d.cm		4D array with the moment coefficients of the airfoils. Dimension 0 is along the blade span for n_span stations, dimension 1 is along the angles of attack, dimension 2 is along the Reynolds number.
af_3d.rated_TSR		Constant tip speed ratio in region II.
af_3d.r_blade	m	1D array of the dimensional spanwise grid defined along the rotor (hub radius to blade tip projected on the plane)
af_3d.rotor_diameter	m	Diameter of the wind turbine rotor specified by the user, defined as 2 x (Rhub + blade length along z) * cos(precone).
af_3d.rthick		1D array of the relative thicknesses of the blade defined along span.
af_3d.chord	m	1D array of the chord values defined along blade span.
blade.compute_coord_xy_dim.chord	m	1D array of the chord values defined along blade span.
blade.compute_coord_xy_dim.section_offset_y	m	1D array of the airfoil position relative to the reference axis, specifying the distance in meters along the chordline from the reference axis to the leading edge. 0 means that the airfoil is pinned at the leading edge, a positive offset means that the leading edge is upstream of the reference axis in local chordline coordinates, and a negative offset that the leading edge aft of the reference axis.
blade.compute_coord_xy_dim.twist	deg	1D array of the twist values defined along blade span. The twist is defined positive for negative rotations around the z axis (the same as in BeamDyn).
blade.compute_coord_xy_dim.coord_xy_interp		3D array of the non-dimensional x and y airfoil coordinates of the airfoils interpolated along span for n_span stations. The leading edge is place at x=0 and y=0.
blade.compute_coord_xy_dim.ref_axis	m	2D array of the coordinates (x,y,z) of the blade reference axis, defined along blade span. The coordinate system is the one of BeamDyn: it is placed at blade root with x pointing the suction side of the blade, y pointing the trailing edge and z along the blade span. A standard configuration will have negative x values (prebend), if swept positive y values, and positive z values.
blade.compute_reynolds.rho	kg/m**3
blade.compute_reynolds.mu	kg/m/s	Dynamic viscosity of air
blade.compute_reynolds.chord	m
blade.compute_reynolds.r_blade	m	1D array of the dimensional spanwise grid defined along the rotor (hub radius to blade tip projected on the plane)
blade.compute_reynolds.rotor_diameter	m	Diameter of the wind turbine rotor specified by the user, defined as 2 x (Rhub + blade length along z) * cos(precone).
blade.compute_reynolds.maxOmega	rad/s	Maximum allowed rotor speed.
blade.compute_reynolds.max_TS	m/s	Maximum allowed blade tip speed.
blade.compute_reynolds.V_out	m/s	Cut out wind speed. This is the wind speed where region III ends.
blade.high_level_blade_props.blade_ref_axis_user	m	2D array of the coordinates (x,y,z) of the blade reference axis, defined along blade span. The coordinate system is the one of BeamDyn: it is placed at blade root with x pointing the suction side of the blade, y pointing the trailing edge and z along the blade span. A standard configuration will have negative x values (prebend), if swept positive y values, and positive z values.
blade.high_level_blade_props.rotor_diameter_user	m	Diameter of the rotor specified by the user, defined as 2 x (Rhub + blade length along z) * cos(precone).
blade.high_level_blade_props.hub_radius	m	Radius of the hub. It defines the distance of the blade root from the rotor center along the coned line.
blade.high_level_blade_props.cone	deg	Cone angle of the rotor. It defines the angle between the rotor plane and the blade pitch axis. A standard machine has positive values.
blade.high_level_blade_props.chord	m	1D array of the chord values defined along blade span.
blade.high_level_blade_props.n_blades	n/a	Number of blades of the rotor.
blade.interp_airfoils.af_position		1D array of the non dimensional positions of the airfoils af_master defined along blade span.
blade.interp_airfoils.s		1D array of the non-dimensional spanwise grid defined along blade axis (0-blade root, 1-blade tip)
blade.interp_airfoils.section_offset_y	m	1D array of the airfoil position relative to the reference axis, specifying the distance in meters along the chordline from the reference axis to the leading edge. 0 means that the airfoil is pinned at the leading edge, a positive offset means that the leading edge is upstream of the reference axis in local chordline coordinates, and a negative offset that the leading edge aft of the reference axis..
blade.interp_airfoils.chord	m	1D array of the chord values defined along blade span.
blade.interp_airfoils.ac		1D array of the aerodynamic centers of each airfoil.
blade.interp_airfoils.rthick_master		1D array of the relative thicknesses of each airfoil.
blade.interp_airfoils.aoa	deg	1D array of the angles of attack used to define the polars of the airfoils. All airfoils defined in openmdao share this grid.
blade.interp_airfoils.cl		4D array with the lift coefficients of the airfoils. Dimension 0 is along the different airfoils defined in the yaml, dimension 1 is along the angles of attack, dimension 2 is along the Reynolds number.
blade.interp_airfoils.cd		4D array with the drag coefficients of the airfoils. Dimension 0 is along the different airfoils defined in the yaml, dimension 1 is along the angles of attack, dimension 2 is along the Reynolds number.
blade.interp_airfoils.cm		4D array with the moment coefficients of the airfoils. Dimension 0 is along the different airfoils defined in the yaml, dimension 1 is along the angles of attack, dimension 2 is along the Reynolds number.
blade.interp_airfoils.coord_xy		3D array of the x and y airfoil coordinates of the n_af_master airfoils used along span.
blade.interp_airfoils.rthick_yaml		1D array of the relative thicknesses of the blade defined along span.
blade.pa.s		1D array of the non-dimensional spanwise grid defined along blade axis (0-blade root, 1-blade tip)
blade.pa.s_opt_twist		1D array of the non-dimensional spanwise grid defined along blade axis to optimize the blade twist angle
blade.pa.twist_opt	rad	1D array of the twist angle being optimized at the n_opt locations.
blade.pa.s_opt_chord		1D array of the non-dimensional spanwise grid defined along blade axis to optimize the blade chord
blade.pa.chord_opt	m	1D array of the chord being optimized at the n_opt locations.
blade.ps.s		1D array of the non-dimensional spanwise grid defined along blade axis (0-blade root, 1-blade tip)
blade.ps.layer_thickness_original	m	2D array of the thickness of the layers of the blade structure. The first dimension represents each layer, the second dimension represents each entry along blade span.
blade.ps.s_opt_layer_0
blade.ps.layer_0_opt	m
blade.ps.s_opt_layer_1
blade.ps.layer_1_opt	m
blade.ps.s_opt_layer_2
blade.ps.layer_2_opt	m
blade.ps.s_opt_layer_3
blade.ps.layer_3_opt	m
blade.ps.s_opt_layer_4
blade.ps.layer_4_opt	m
blade.ps.s_opt_layer_5
blade.ps.layer_5_opt	m
blade.ps.s_opt_layer_6
blade.ps.layer_6_opt	m
blade.ps.s_opt_layer_7
blade.ps.layer_7_opt	m
blade.ps.s_opt_layer_8
blade.ps.layer_8_opt	m
blade.ps.s_opt_layer_9
blade.ps.layer_9_opt	m
blade.ps.s_opt_layer_10
blade.ps.layer_10_opt	m
blade.ps.s_opt_layer_11
blade.ps.layer_11_opt	m
blade.ps.s_opt_layer_12
blade.ps.layer_12_opt	m
blade.ps.s_opt_layer_13
blade.ps.layer_13_opt	m
blade.ps.s_opt_layer_14
blade.ps.layer_14_opt	m
blade.ps.s_opt_layer_15
blade.ps.layer_15_opt	m
blade.ps.s_opt_layer_16
blade.ps.layer_16_opt	m
blade.ps.s_opt_layer_17
blade.ps.layer_17_opt	m
blade.structure.web_start_nd_yaml		2D array of the non-dimensional start point defined along the outer profile of a web. The TE suction side is 0, the TE pressure side is 1. The first dimension represents each web, the second dimension represents each entry along blade span.
blade.structure.web_end_nd_yaml		2D array of the non-dimensional end point defined along the outer profile of a web. The TE suction side is 0, the TE pressure side is 1. The first dimension represents each web, the second dimension represents each entry along blade span.
blade.structure.web_offset	m	2D array of the dimensional offset of a web with respect to the reference axis. The first dimension represents each web, the second dimension represents each entry along blade span.
blade.structure.web_rotation	deg	1D array of the dimensional rotation of a web with respect to the reference axis. The dimension represents each web.
blade.structure.layer_start_nd_yaml		2D array of the start_nd_arc of the layers. The first dimension represents each layer, the second dimension represents span.
blade.structure.layer_end_nd_yaml		2D array of the end_nd_arc of the layers. The first dimension represents each layer, the second dimension represents span.
blade.structure.layer_width	m	2D array of the width of the layers. The first dimension represents each layer, the second dimension represents span.
blade.structure.layer_offset	m	2D array of the dimensional offset of a layer with respect to the reference axis. The first dimension represents each layer, the second dimension represents each entry along blade span.
blade.structure.layer_rotation	deg	1D array of the dimensional rotation of a layer with respect to the reference axis. The dimension represents each layer.
blade.structure.coord_xy_dim	m	3D array of the dimensional x and y airfoil coordinates of the airfoils interpolated along span for n_span stations. The origin is placed at the pitch axis.
blade.structure.build_web	n/a	1D array of boolean values indicating whether to build a web from offset and rotation.
blade.structure.build_layer	n/a	1D array of boolean values indicating how to build a layer. 0 - start and end are set constant, 1 - from offset and rotation suction side, 2 - from offset and rotation pressure side, 3 - LE and width, 4 - TE SS width, 5 - TE PS width, 6 - locked to another layer. Negative values place the layer on webs (-1 first web, -2 second web, etc.).
blade.structure.index_layer_start	n/a	Index used to fix a layer to another
blade.structure.index_layer_end	n/a	Index used to fix a layer to another
high_level_tower_props.tower_ref_axis_user	m	2D array of the coordinates (x,y,z) of the tower reference axis. The coordinate system is the global coordinate system of OpenFAST: it is placed at tower base with x pointing downwind, y pointing on the side and z pointing vertically upwards. A standard tower configuration will have zero x and y values and positive z values.
high_level_tower_props.distance_tt_hub	m	Vertical distance from tower top to hub center.
high_level_tower_props.hub_height_user	m	Height of the hub specified by the user.
high_level_tower_props.rotor_diameter	m	Scalar of the rotor diameter, defined as 2 x (Rhub + blade length along z) * cos(precone).
hub.diameter	m
materials.rho_fiber	kg/m**3	1D array of the density of the fibers of the materials.
materials.rho	kg/m**3	1D array of the density of the materials. For composites, this is the density of the laminate.
materials.rho_area_dry	kg/m**2	1D array of the dry aerial density of the composite fabrics. Non-composite materials are kept at 0.
materials.ply_t_from_yaml	m	1D array of the ply thicknesses of the materials. Non-composite materials are kept at 0.
materials.fvf_from_yaml		1D array of the non-dimensional fiber volume fraction of the composite materials. Non-composite materials are kept at 0.
materials.fwf_from_yaml		1D array of the non-dimensional fiber weight- fraction of the composite materials. Non-composite materials are kept at 0.
materials.name	n/a	1D array of names of materials.
materials.orth	n/a	1D array of flags to set whether a material is isotropic (0) or orthtropic (1). Each entry represents a material.
monopile.ref_axis	m	2D array of the coordinates (x,y,z) of the tower reference axis. The coordinate system is the global coordinate system of OpenFAST: it is placed at tower base with x pointing downwind, y pointing on the side and z pointing vertically upwards. A standard tower configuration will have zero x and y values and positive z values.
tower_grid.ref_axis	m	2D array of the coordinates (x,y,z) of the tower reference axis. The coordinate system is the global coordinate system of OpenFAST: it is placed at tower base with x pointing downwind, y pointing on the side and z pointing vertically upwards. A standard tower configuration will have zero x and y values and positive z values.
drivese.bear1.D_bearing	m
drivese.bear1.D_shaft	m
drivese.bear1.mb_mass_user	kg
drivese.bear1.bearing_type	n/a
drivese.bear2.D_bearing	m
drivese.bear2.D_shaft	m
drivese.bear2.mb_mass_user	kg
drivese.bear2.bearing_type	n/a
drivese.rotor_diameter	m
drivese.rated_torque	N*m
drivese.brake_mass_user	kg
drivese.s_rotor	m
drivese.s_gearbox	m
drivese.lss_spring_constant	N*m/rad
drivese.hss_spring_constant	N*m/rad
drivese.gear_ratio
drivese.damping_ratio
drivese.blades_I	kg*m**2
drivese.hub_system_I	kg*m**2
drivese.drivetrain_spring_constant_user	N*m/rad
drivese.drivetrain_damping_coefficient_user	N*m*s/rad
drivese.machine_rating	kW
drivese.D_top	m
drivese.converter_mass_user	kg
drivese.transformer_mass_user	kg
drivese.gearbox_mass_user	kg
drivese.gearbox_radius_user	m
drivese.gearbox_length_user	m
drivese.gear_configuration	n/a
drivese.planet_numbers	n/a
drivese.generator.u_allow_s	m
drivese.generator.u_as	m
drivese.generator.z_allow_s	m
drivese.generator.z_as	m
drivese.generator.y_allow_s	m
drivese.generator.y_as	m
drivese.generator.b_allow_s	m
drivese.generator.b_st	m
drivese.generator.u_allow_r	m
drivese.generator.u_ar	m
drivese.generator.y_allow_r	m
drivese.generator.y_ar	m
drivese.generator.z_allow_r	m
drivese.generator.z_ar	m
drivese.generator.b_allow_r	m
drivese.generator.b_arm	m
drivese.generator.TC1	m**3
drivese.generator.TC2r	m**3
drivese.generator.TC2s	m**3
drivese.generator.B_g	T
drivese.generator.B_smax	T
drivese.generator.K_rad
drivese.generator.K_rad_LL
drivese.generator.K_rad_UL
drivese.generator.D_ratio
drivese.generator.D_ratio_LL
drivese.generator.D_ratio_UL
drivese.generator.shaft_rpm	rpm
drivese.generator.eandm_efficiency
drivese.generator.C_Cu	USD/kg
drivese.generator.C_Fe	USD/kg
drivese.generator.C_Fes	USD/kg
drivese.generator.C_PM	USD/kg
drivese.generator.Copper	kg
drivese.generator.Iron	kg
drivese.generator.mass_PM	kg
drivese.generator.Structural_mass	kg
drivese.generator.B_r	T
drivese.generator.E	Pa
drivese.generator.G	Pa
drivese.generator.P_Fe0e	W/kg
drivese.generator.P_Fe0h	W/kg
drivese.generator.S_N
drivese.generator.alpha_p
drivese.generator.b_r_tau_r
drivese.generator.b_ro	m
drivese.generator.b_s_tau_s
drivese.generator.b_so	m
drivese.generator.cofi
drivese.generator.freq	Hz
drivese.generator.h_i	m
drivese.generator.h_sy0
drivese.generator.h_w	m
drivese.generator.k_fes
drivese.generator.k_fillr
drivese.generator.k_fills
drivese.generator.k_s
drivese.generator.mu_0	m*kg/s**2/A**2
drivese.generator.mu_r	m*kg/s**2/A**2
drivese.generator.p
drivese.generator.phi	rad
drivese.generator.ratio_mw2pp
drivese.generator.resist_Cu	ohm/m
drivese.generator.sigma	Pa
drivese.generator.v
drivese.generator.y_tau_p
drivese.generator.y_tau_pr
drivese.generator.I_0	A
drivese.generator.d_r	m
drivese.generator.h_m	m
drivese.generator.h_0	m
drivese.generator.h_s	m
drivese.generator.len_s	m
drivese.generator.n_r
drivese.generator.rad_ag	m
drivese.generator.t_wr	m
drivese.generator.n_s
drivese.generator.d_s	m
drivese.generator.t_ws	m
drivese.generator.D_shaft	m
drivese.generator.rho_Copper	kg/m**3
drivese.generator.rho_Fe	kg/m**3
drivese.generator.rho_Fes	kg/m**3
drivese.generator.rho_PM	kg/m**3
drivese.generator_mass_user	kg
drivese.generator.P_mech	W
drivese.generator.N_c
drivese.generator.b
drivese.generator.c
drivese.generator.E_p	V
drivese.generator.h_yr	m
drivese.generator.h_ys	m
drivese.generator.h_sr	m
drivese.generator.h_ss	m
drivese.generator.t_r	m
drivese.generator.t_s	m
drivese.generator.y_sh	m
drivese.generator.theta_sh	rad
drivese.generator.D_nose	m
drivese.generator.y_bd	m
drivese.generator.theta_bd	rad
drivese.generator.u_allow_pcent
drivese.generator.y_allow_pcent
drivese.generator.z_allow_deg	deg
drivese.generator.B_tmax	T
drivese.generator.m	n/a
drivese.generator.q1	n/a
drivese.generator.q2	n/a
drivese.generator.R_out	m
drivese.generator_stator_mass	kg
drivese.generator_rotor_mass	kg
drivese.generator_mass	kg
drivese.pitch_mass	kg
drivese.pitch_cost	USD
drivese.pitch_I	kg*m**2
drivese.hub_mass	kg
drivese.hub_cost	USD
drivese.hub_cm	m
drivese.hub_I	kg*m**2
drivese.spinner_mass	kg
drivese.spinner_cost	kg
drivese.spinner_cm	m
drivese.spinner_I	kg*m**2
drivese.hub_system_mass_user	kg
drivese.hub_system_cm_user	m
drivese.hub_system_I_user	kg*m**2
drivese.flange_t2shell_t
drivese.flange_OD2hub_D
drivese.flange_ID2flange_OD
drivese.hub_shell.rho	kg/m**3
drivese.max_torque	N*m
drivese.hub_shell.Xy	Pa
drivese.hub_stress_concentration
drivese.hub_shell.metal_cost	USD/kg
drivese.hub_diameter	m
drivese.blade_root_diameter	m
drivese.hub_in2out_circ
drivese.hub_shell_mass_user	kg
drivese.hub_shell.n_blades	n/a
drivese.rated_rpm	rpm
drivese.stop_time	s
drivese.blade_mass	kg
drivese.pitch_system.rho	kg/m**3
drivese.pitch_system.Xy	Pa
drivese.pitch_system_scaling_factor
drivese.pitch_system.BRFM	N*m
drivese.pitch_system_mass_user	kg
drivese.n_blades	n/a
drivese.clearance_hub_spinner	m
drivese.spin_hole_incr
drivese.spinner_gust_ws	m/s
drivese.spinner.composite_Xt	Pa
drivese.spinner.composite_rho	kg/m**3
drivese.spinner.Xy	Pa
drivese.spinner.metal_rho	kg/m**3
drivese.spinner.composite_cost	USD/kg
drivese.spinner.metal_cost	USD/kg
drivese.spinner_mass_user	kg
drivese.n_front_brackets	n/a
drivese.n_rear_brackets	n/a
drivese.L_12	m
drivese.L_h1	m
drivese.L_generator	m
drivese.overhang	m
drivese.drive_height	m
drivese.tilt	deg
drivese.lss_diameter	m
drivese.lss_wall_thickness	m
drivese.lss_rho	kg/m**3
drivese.bedplate_rho	kg/m**3
drivese.bedplate_mass_user	kg
drivese.access_diameter	m
drivese.nose_diameter	m
drivese.nose_wall_thickness	m
drivese.bedplate_wall_thickness	m
drivese.upwind	n/a
drivese.s_lss	m
drivese.hub_system_mass	kg
drivese.hub_system_cm	m
drivese.F_aero_hub	N
drivese.M_aero_hub	N*m
drivese.blades_mass	kg
drivese.blades_cm	m
drivese.s_mb1	m
drivese.s_mb2	m
drivese.generator_rotor_I	kg*m**2
drivese.gearbox_mass	kg
drivese.gearbox_I	kg*m**2
drivese.brake_mass	kg
drivese.brake_I	kg*m**2
drivese.carrier_mass	kg
drivese.carrier_I	kg*m**2
drivese.lss_E	Pa
drivese.lss_G	Pa
drivese.lss_Xy	Pa
drivese.shaft_deflection_allowable	m
drivese.shaft_angle_allowable	rad
drivese.E_mat	Pa
drivese.G_mat	Pa
drivese.Xt_mat	Pa
drivese.Xy_mat	Pa
drivese.wohler_exp_mat
drivese.wohler_A_mat
drivese.rho_mat	kg/m**3
drivese.unit_cost_mat	USD/kg
drivese.material_names	n/a
drivese.lss_material	n/a
drivese.hss_material	n/a
drivese.hub_material	n/a
drivese.spinner_material	n/a
drivese.bedplate_material	n/a
drivese.hvac_mass_coeff	kg/kW/m
drivese.H_bedplate	m
drivese.L_bedplate	m
drivese.R_generator	m
drivese.generator_cm	m
drivese.rho_fiberglass	kg/m**3
drivese.rho_castiron	kg/m**3
drivese.mb1_mass	kg
drivese.mb1_cm	m
drivese.mb1_I	kg*m**2
drivese.mb2_mass	kg
drivese.mb2_cm	m
drivese.mb2_I	kg*m**2
drivese.gearbox_cm	m
drivese.hss_mass	kg
drivese.hss_cm	m
drivese.hss_I	kg*m**2
drivese.brake_cm	m
drivese.generator_I	kg*m**2
drivese.generator_stator_I	kg*m**2
drivese.nose_mass	kg
drivese.nose_cm	m
drivese.nose_I	kg*m**2
drivese.lss_mass	kg
drivese.lss_cm	m
drivese.lss_I	kg*m**2
drivese.converter_mass	kg
drivese.converter_cm	m
drivese.converter_I	kg*m**2
drivese.transformer_mass	kg
drivese.transformer_cm	m
drivese.transformer_I	kg*m**2
drivese.yaw_mass	kg
drivese.yaw_cm	m
drivese.yaw_I	kg*m**2
drivese.bedplate_mass	kg
drivese.bedplate_cm	m
drivese.bedplate_I	kg*m**2
drivese.hvac_mass	kg
drivese.hvac_cm	m
drivese.hvac_I	m
drivese.platform_mass	kg
drivese.platform_cm	m
drivese.platform_I	m
drivese.cover_mass	kg
drivese.cover_cm	m
drivese.cover_I	m
drivese.x_bedplate	m
drivese.above_yaw_mass_user	kg
drivese.above_yaw_cm_user	m
drivese.above_yaw_I_user	kg*m**2
drivese.constr_height	m
drivese.uptower	n/a
drivese.s_nose	m
drivese.z_bedplate	m
drivese.x_bedplate_inner	m
drivese.z_bedplate_inner	m
drivese.x_bedplate_outer	m
drivese.z_bedplate_outer	m
drivese.D_bedplate	m
drivese.t_bedplate	m
drivese.mb1_max_defl_ang	rad
drivese.mb2_max_defl_ang	rad
drivese.s_stator	m
drivese.F_mb1	N
drivese.F_mb2	N
drivese.M_mb1	N*m
drivese.M_mb2	N*m
drivese.other_mass	kg
drivese.bedplate_E	Pa
drivese.bedplate_G	Pa
drivese.bedplate_Xy	Pa
drivese.stator_deflection_allowable	m
drivese.stator_angle_allowable	rad
drivese.L_drive	m
drivese.shaft_start	m
drivese.nacelle_mass	kg
drivese.nacelle_cm	m
drivese.nacelle_I_TT	kg*m**2
drivese.minimum_rpm	rpm
drivese.yaw.rho	kg/m**3
drivese.yaw_mass_user	kg
rotorse.rp.aep.CDF_V	m/s	cumulative distribution function evaluated at each wind speed
rotorse.rp.aep.P	W	power curve (power)
rotorse.rp.aep.lossFactor		multiplicative factor for availability and other losses (soiling, array, etc.)
rotorse.rp.cdf.x	m/s	corresponding reference height
rotorse.rp.cdf.k		shape or form factor
rotorse.rp.cdf.xbar	m/s	mean value of distribution
rotorse.rp.gust.V_mean	m/s	IEC average wind speed for turbine class
rotorse.rp.gust.V_hub	m/s	hub height wind speed
rotorse.rp.gust.turbulence_class	n/a	IEC turbulence class
rotorse.rp.v_min	m/s	cut-in wind speed
rotorse.rp.v_max	m/s	cut-out wind speed
rotorse.rp.rated_power	W	electrical rated power
rotorse.rp.omega_min	rpm	minimum allowed rotor rotation speed
rotorse.rp.omega_max	rpm	maximum allowed rotor rotation speed
rotorse.rp.control_maxTS	m/s	maximum allowed blade tip speed
rotorse.rp.powercurve.ps_percent		Scalar applied to the max torque within RotorSE for peak thrust shaving. Only used if peak_thrust_shaving is True.
rotorse.rp.powercurve.gearbox_efficiency
rotorse.rp.powercurve.generator_efficiency		Generator efficiency at various rpm values to support table lookup
rotorse.rp.powercurve.lss_rpm	rpm	Low speed shaft RPM values at which the generator efficiency values are given
rotorse.rp.drivetrainType	n/a
rotorse.rp.powercurve.V	m/s	wind vector
rotorse.rp.powercurve.Omega	rpm	rotor rotational speed
rotorse.rp.powercurve.P	W	rotor electrical power
rotorse.rs.aero_gust.V_load	m/s
rotorse.rs.Omega_load	rpm
rotorse.rs.pitch_load	deg
rotorse.rs.aero_gust.azimuth_load	deg
rotorse.rs.aero_hub_loads.V_load	m/s
rotorse.rs.aero_hub_loads.nSector	n/a
rotorse.rs.brs.rootD	m	Blade root outer diameter / Chord at blade span station 0
rotorse.rs.brs.layer_thickness	m	2D array of the thickness of the layers of the blade structure. The first dimension represents each layer, the second dimension represents each entry along blade span.
rotorse.rs.brs.layer_start_nd		2D array of the non-dimensional start point defined along the outer profile of a layer. The TE suction side is 0, the TE pressure side is 1. The first dimension represents each layer, the second dimension represents each entry along blade span.
rotorse.rs.brs.layer_end_nd		2D array of the non-dimensional end point defined along the outer profile of a layer. The TE suction side is 0, the TE pressure side is 1. The first dimension represents each layer, the second dimension represents each entry along blade span.
rotorse.rs.brs.root_M	N*m	Blade root moment in blade c.s.
rotorse.rs.brs.s_f		Safety factor
rotorse.rs.brs.d_f	m	Diameter of the fastener
rotorse.rs.brs.sigma_max	Pa	Max stress on bolt
rotorse.rs.constr.strainU_spar		strain in spar cap on upper surface at location xu,yu_strain with loads P_strain
rotorse.rs.constr.strainL_spar		strain in spar cap on lower surface at location xl,yl_strain with loads P_strain
rotorse.rs.constr.strainU_te		strain in trailing edge on upper surface at location xu,yu_strain with loads P_strain
rotorse.rs.constr.strainL_te		strain in trailing edge on lower surface at location xl,yl_strain with loads P_strain
rotorse.rs.constr.max_strainU_spar		maximum strain in spar cap suction side
rotorse.rs.constr.max_strainL_spar		maximum strain in spar cap pressure side
rotorse.rs.constr.max_strainU_te		maximum strain in spar cap suction side
rotorse.rs.constr.max_strainL_te		maximum strain in spar cap pressure side
rotorse.s		1D array of the non-dimensional spanwise grid defined along blade axis (0-blade root, 1-blade tip)
rotorse.rs.constr.s_opt_spar_cap_ss		1D array of the non-dimensional spanwise grid defined along blade axis to optimize the blade spar cap suction side
rotorse.rs.constr.s_opt_spar_cap_ps		1D array of the non-dimensional spanwise grid defined along blade axis to optimize the blade spar cap pressure side
rotorse.rs.constr.s_opt_te_ss		1D array of the non-dimensional spanwise grid defined along blade axis to optimize the blade trailing edge suction side
rotorse.rs.constr.s_opt_te_ps		1D array of the non-dimensional spanwise grid defined along blade axis to optimize the blade trailing edge pressure side
rotorse.rs.constr.rated_Omega	rpm	rotor rotation speed at rated
rotorse.rs.constr.flap_mode_freqs	Hz	Frequencies associated with mode shapes in the flap direction
rotorse.rs.constr.edge_mode_freqs	Hz	Frequencies associated with mode shapes in the edge direction
rotorse.rs.constr.tors_mode_freqs	Hz	Frequencies associated with mode shapes in the torsional direction
rotorse.rs.constr.blade_number	n/a
rotorse.blade_span_cg	m	Distance along the blade span for its center of gravity
rotorse.rs.x_az	m	location of blade in azimuth x-coordinate system (prebend)
rotorse.rs.y_az	m	location of blade in azimuth y-coordinate system (sweep)
rotorse.rs.z_az	m	location of blade in azimuth z-coordinate system (from root to tip)
rotorse.rs.frame.Px_af	N/m	distributed load (force per unit length) in airfoil x-direction
rotorse.rs.frame.Py_af	N/m	distributed load (force per unit length) in airfoil y-direction
rotorse.rs.frame.Pz_af	N/m	distributed load (force per unit length) in airfoil z-direction
rotorse.A	m**2	airfoil cross section material area
rotorse.rs.strains.EI11	N*m**2	stiffness w.r.t principal axis 1
rotorse.rs.strains.EI22	N*m**2	stiffness w.r.t principal axis 2
rotorse.rs.strains.alpha	deg	Angle between blade c.s. and principal axes
rotorse.rs.strains.M1	N*m	distribution along blade span of bending moment w.r.t principal axis 1
rotorse.rs.strains.M2	N*m	distribution along blade span of bending moment w.r.t principal axis 2
rotorse.rs.strains.F3	N	axial resultant along blade span
rotorse.xu_spar		x-position of midpoint of spar cap on upper surface for strain calculation
rotorse.xl_spar		x-position of midpoint of spar cap on lower surface for strain calculation
rotorse.yu_spar		y-position of midpoint of spar cap on upper surface for strain calculation
rotorse.yl_spar		y-position of midpoint of spar cap on lower surface for strain calculation
rotorse.xu_te		x-position of midpoint of trailing-edge panel on upper surface for strain calculation
rotorse.xl_te		x-position of midpoint of trailing-edge panel on lower surface for strain calculation
rotorse.yu_te		y-position of midpoint of trailing-edge panel on upper surface for strain calculation
rotorse.yl_te		y-position of midpoint of trailing-edge panel on lower surface for strain calculation
rotorse.rs.tip_pos.dx_tip	m	deflection at tip in blade x-direction
rotorse.rs.tip_pos.dy_tip	m	deflection at tip in blade y-direction
rotorse.rs.tip_pos.dz_tip	m	deflection at tip in blade z-direction
rotorse.rs.tip_pos.3d_curv_tip	deg	total coning angle including precone and curvature
rotorse.rs.tip_pos.dynamicFactor		a dynamic amplification factor to adjust the static deflection calculation
rotorse.rs.tot_loads_gust.aeroloads_Px	N/m	distributed loads in blade-aligned x-direction
rotorse.rs.tot_loads_gust.aeroloads_Py	N/m	distributed loads in blade-aligned y-direction
rotorse.rs.tot_loads_gust.aeroloads_Pz	N/m	distributed loads in blade-aligned z-direction
rotorse.rs.tot_loads_gust.aeroloads_Omega	rpm	rotor rotation speed
rotorse.rs.tot_loads_gust.aeroloads_pitch	deg	pitch angle
rotorse.rs.tot_loads_gust.aeroloads_azimuth	deg	azimuthal angle
rotorse.rs.3d_curv	deg	total cone angle from precone and curvature
rotorse.rs.tot_loads_gust.dynamicFactor		a dynamic amplification factor to adjust the static deflection calculation
rotorse.stall_check.aoa_along_span	deg	Angle of attack along blade span
rotorse.stall_check.stall_margin	deg	Minimum margin from the stall angle
rotorse.stall_check.min_s		Minimum nondimensional coordinate along blade span where to define the constraint (blade root typically stalls)
landbosse.blade_drag_coefficient
landbosse.blade_lever_arm	m
landbosse.blade_install_cycle_time	h
landbosse.blade_offload_hook_height	m
landbosse.blade_offload_cycle_time	h
landbosse.blade_drag_multiplier
landbosse.blade_surface_area	m**2
landbosse.foundation_height	m
landbosse.tower_section_length_m	m
landbosse.nacelle_mass	kg
landbosse.tower_mass	kg
landbosse.blade_mass	kg	The mass of one rotor blade.
landbosse.hub_mass	kg	Mass of the rotor hub
landbosse.crane_breakdown_fraction		0 means the crane is never broken down. 1 means it is broken down every turbine.
landbosse.construct_duration		Total project construction time (months)
landbosse.hub_height_meters	m	Hub height m
landbosse.rotor_diameter_m	m	Rotor diameter m
landbosse.wind_shear_exponent		Wind shear exponent
landbosse.turbine_capex_kW	USD/kW	Turbine capital cost
landbosse.turbine_rating_MW	MW	Turbine rating MW
landbosse.fuel_cost_usd_per_gal		Fuel cost USD/gal
landbosse.breakpoint_between_base_and_topping_percent		Breakpoint between base and topping (percent)
landbosse.turbine_spacing_rotor_diameters		Turbine spacing (times rotor diameter)
landbosse.depth	m	Foundation depth m
landbosse.rated_thrust_N	N	Rated Thrust (N)
landbosse.bearing_pressure_n_m2		Bearing Pressure (n/m2)
landbosse.gust_velocity_m_per_s	m/s	50-year Gust Velocity (m/s)
landbosse.road_length_adder_m	m	Road length adder (m)
landbosse.fraction_new_roads		Percent of roads that will be constructed (0.0 - 1.0)
landbosse.road_quality		Road Quality (0-1)
landbosse.line_frequency_hz	Hz	Line Frequency (Hz)
landbosse.row_spacing_rotor_diameters		Row spacing (times rotor diameter)
landbosse.trench_len_to_substation_km	km	Combined Homerun Trench Length to Substation (km)
landbosse.distance_to_interconnect_mi	mi	Distance to interconnect (miles)
landbosse.interconnect_voltage_kV	kV	Interconnect Voltage (kV)
landbosse.critical_speed_non_erection_wind_delays_m_per_s	m/s	Non-Erection Wind Delay Critical Speed (m/s)
landbosse.critical_height_non_erection_wind_delays_m	m	Non-Erection Wind Delay Critical Height (m)
landbosse.road_width_ft	ft	Road width (ft)
landbosse.road_thickness		Road thickness (in)
landbosse.crane_width	m	Crane width (m)
landbosse.overtime_multiplier		Overtime multiplier
landbosse.markup_contingency		Markup contingency
landbosse.markup_warranty_management		Markup warranty management
landbosse.markup_sales_and_use_tax		Markup sales and use tax
landbosse.markup_overhead		Markup overhead
landbosse.markup_profit_margin		Markup profit margin
landbosse.Mass tonne	t
landbosse.development_labor_cost_usd	USD	The cost of labor in the development phase
landbosse.labor_cost_multiplier		Labor cost multiplier
landbosse.commissioning_cost_kW	USD/kW	Commissioning cost.
landbosse.decommissioning_cost_kW	USD/kW	Decommissioning cost.
landbosse.road_distributed_wind	n/a
landbosse.num_turbines	n/a	Number of turbines in project
landbosse.number_of_blades	n/a	Number of blades on the rotor
landbosse.user_defined_home_run_trench	n/a	Flag for user-defined home run trench length (0 = no; 1 = yes)
landbosse.allow_same_flag	n/a	Allow same crane for base and topping (True or False)
landbosse.hour_day	n/a	Dictionary of normal and long hours for construction in a day in the form of {‘long’: 24, ‘normal’: 10}
landbosse.time_construct	n/a	One of the keys in the hour_day dictionary to specify how many hours per day construction happens.
landbosse.user_defined_distance_to_grid_connection	n/a	Flag for user-defined home run trench length (True or False)
landbosse.rate_of_deliveries	n/a	Rate of deliveries (turbines per week)
landbosse.new_switchyard	n/a	New Switchyard (True or False)
landbosse.num_hwy_permits	n/a	Number of highway permits
landbosse.num_access_roads	n/a	Number of access roads
landbosse.site_facility_building_area_df	n/a	site_facility_building_area DataFrame
landbosse.components	n/a	Dataframe of components for tower, blade, nacelle
landbosse.crane_specs	n/a	Dataframe of specifications of cranes
landbosse.weather_window	n/a	Dataframe of wind toolkit data
landbosse.crew	n/a	Dataframe of crew configurations
landbosse.crew_price	n/a	Dataframe of costs per hour for each type of worker.
landbosse.equip	n/a	Collections of equipment to perform erection operations.
landbosse.equip_price	n/a	Prices for various type of equipment.
landbosse.rsmeans	n/a	RSMeans price data
landbosse.cable_specs	n/a	cable specs for collection system
landbosse.material_price	n/a	Prices of materials for foundations and roads
landbosse.project_data	n/a	Dictionary of all dataframes of data
drivese.s_drive	m
drivese.bedplate_flange_width	m
drivese.bedplate_flange_thickness	m
drivese.bedplate_web_height	m
drivese.bedplate_web_thickness	m
drivese.s_generator	m
drivese.F_torq	N
drivese.F_generator	N
drivese.M_torq	N*m
drivese.M_generator	N*m
drivese.generator.S_Nmax
drivese.generator.B_symax	T
drivese.s_hss	m
drivese.hss_diameter	m
drivese.hss_wall_thickness	m
drivese.hss_E	Pa
drivese.hss_G	Pa
drivese.hss_rho	kg/m**3
drivese.hss_Xy	Pa
drivese.L_hss	m
drivese.L_gearbox	m
floatingse.Hsig_wave	m
floatingse.variable_ballast_mass	kg
floatingse.fairlead_radius	m
floatingse.fairlead	m
floatingse.survival_heel	rad
floatingse.member0_main_column:nodes_xyz	m
floatingse.member0_main_column:constr_ballast_capacity
floatingse.member1_column1:nodes_xyz	m
floatingse.member1_column1:constr_ballast_capacity
floatingse.member2_column2:nodes_xyz	m
floatingse.member2_column2:constr_ballast_capacity
floatingse.member3_column3:nodes_xyz	m
floatingse.member3_column3:constr_ballast_capacity
floatingse.member4_Y_pontoon_upper1:nodes_xyz	m
floatingse.member4_Y_pontoon_upper1:constr_ballast_capacity
floatingse.member5_Y_pontoon_upper2:nodes_xyz	m
floatingse.member5_Y_pontoon_upper2:constr_ballast_capacity
floatingse.member6_Y_pontoon_upper3:nodes_xyz	m
floatingse.member6_Y_pontoon_upper3:constr_ballast_capacity
floatingse.member7_Y_pontoon_lower1:nodes_xyz	m
floatingse.member7_Y_pontoon_lower1:constr_ballast_capacity
floatingse.member8_Y_pontoon_lower2:nodes_xyz	m
floatingse.member8_Y_pontoon_lower2:constr_ballast_capacity
floatingse.member9_Y_pontoon_lower3:nodes_xyz	m
floatingse.member9_Y_pontoon_lower3:constr_ballast_capacity
floatingse.platform_Iwaterx	m**4
floatingse.platform_Iwatery	m**4
floatingse.platform_displacement	m**3
floatingse.platform_center_of_buoyancy	m
floatingse.system_center_of_mass	m
floatingse.transition_node	m
floatingse.turbine_F	N
floatingse.turbine_M	N*m
floatingse.max_surge_restoring_force	N
floatingse.operational_heel_restoring_force	N
floatingse.survival_heel_restoring_force	N
floatingse.platform_mass	kg
floatingse.platform_hull_center_of_mass	m
floatingse.platform_added_mass	kg
floatingse.platform_nodes	m
floatingse.platform_Fnode	N
floatingse.platform_Rnode	m
floatingse.platform_elem_n1
floatingse.platform_elem_n2
floatingse.platform_elem_t	m
floatingse.platform_elem_L	m
floatingse.platform_elem_A	m**2
floatingse.platform_elem_Asx	m**2
floatingse.platform_elem_Asy	m**2
floatingse.platform_elem_Ixx	kg*m**2
floatingse.platform_elem_Iyy	kg*m**2
floatingse.platform_elem_J0	kg*m**2
floatingse.platform_elem_rho	kg/m**3
floatingse.platform_elem_E	Pa
floatingse.platform_elem_G	Pa
floatingse.platform_elem_TorsC	m**3
floatingse.platform_elem_Px1	N/m
floatingse.platform_elem_Px2	N/m
floatingse.platform_elem_Py1	N/m
floatingse.platform_elem_Py2	N/m
floatingse.platform_elem_Pz1	N/m
floatingse.platform_elem_Pz2	N/m
floatingse.transition_piece_mass	kg
floatingse.transition_piece_I	kg*m**2
floatingse.mooring_neutral_load	N
floatingse.mooring_fairlead_joints	m
floatingse.mooring_stiffness	N/m
floatingse.variable_center_of_mass	m
floatingse.variable_I	kg*m**2
floatingse.member0_main_column:Px	N/m
floatingse.member0_main_column:Py	N/m
floatingse.member0_main_column:Pz	N/m
floatingse.member0_main_column:qdyn	Pa
floatingse.member1_column1:Px	N/m
floatingse.member1_column1:Py	N/m
floatingse.member1_column1:Pz	N/m
floatingse.member1_column1:qdyn	Pa
floatingse.member2_column2:Px	N/m
floatingse.member2_column2:Py	N/m
floatingse.member2_column2:Pz	N/m
floatingse.member2_column2:qdyn	Pa
floatingse.member3_column3:Px	N/m
floatingse.member3_column3:Py	N/m
floatingse.member3_column3:Pz	N/m
floatingse.member3_column3:qdyn	Pa
floatingse.member4_Y_pontoon_upper1:Px	N/m
floatingse.member4_Y_pontoon_upper1:Py	N/m
floatingse.member4_Y_pontoon_upper1:Pz	N/m
floatingse.member4_Y_pontoon_upper1:qdyn	Pa
floatingse.member5_Y_pontoon_upper2:Px	N/m
floatingse.member5_Y_pontoon_upper2:Py	N/m
floatingse.member5_Y_pontoon_upper2:Pz	N/m
floatingse.member5_Y_pontoon_upper2:qdyn	Pa
floatingse.member6_Y_pontoon_upper3:Px	N/m
floatingse.member6_Y_pontoon_upper3:Py	N/m
floatingse.member6_Y_pontoon_upper3:Pz	N/m
floatingse.member6_Y_pontoon_upper3:qdyn	Pa
floatingse.member7_Y_pontoon_lower1:Px	N/m
floatingse.member7_Y_pontoon_lower1:Py	N/m
floatingse.member7_Y_pontoon_lower1:Pz	N/m
floatingse.member7_Y_pontoon_lower1:qdyn	Pa
floatingse.member8_Y_pontoon_lower2:Px	N/m
floatingse.member8_Y_pontoon_lower2:Py	N/m
floatingse.member8_Y_pontoon_lower2:Pz	N/m
floatingse.member8_Y_pontoon_lower2:qdyn	Pa
floatingse.member9_Y_pontoon_lower3:Px	N/m
floatingse.member9_Y_pontoon_lower3:Py	N/m
floatingse.member9_Y_pontoon_lower3:Pz	N/m
floatingse.member9_Y_pontoon_lower3:qdyn	Pa
floatingse.memload0.env.distLoads.windLoads_Px	N/m
floatingse.memload0.env.distLoads.windLoads_Py	N/m
floatingse.memload0.env.distLoads.windLoads_Pz	N/m
floatingse.memload0.env.distLoads.windLoads_qdyn	N/m**2
floatingse.memload0.env.distLoads.windLoads_z	m
floatingse.memload0.env.distLoads.windLoads_beta	deg
floatingse.memload0.env.distLoads.waveLoads_Px	N/m
floatingse.memload0.env.distLoads.waveLoads_Py	N/m
floatingse.memload0.env.distLoads.waveLoads_Pz	N/m
floatingse.memload0.env.distLoads.waveLoads_qdyn	N/m**2
floatingse.memload0.env.distLoads.waveLoads_z	m
floatingse.memload0.env.distLoads.waveLoads_beta	deg
floatingse.memload0.z_global	m
floatingse.yaw	deg
floatingse.rho_water	kg/m**3
floatingse.z0	m
floatingse.water_depth	m
floatingse.Uc	m/s	mean current speed
floatingse.Tsig_wave	s
floatingse.memload0.env.waveLoads.U	m/s
floatingse.memload0.env.waveLoads.A	m/s**2
floatingse.memload0.env.waveLoads.p	N/m**2
floatingse.memload0.outer_diameter_full	m
floatingse.beta_wave	deg
floatingse.mu_water	kg/m/s
floatingse.memload0.ca_usr
floatingse.memload0.cd_usr
floatingse.env.Uref	m/s
floatingse.wind_reference_height	m
floatingse.shearExp
floatingse.memload0.env.windLoads.U	m/s
floatingse.beta_wind	deg
floatingse.rho_air	kg/m**3
floatingse.mu_air	kg/m/s
floatingse.member0_main_column:joint1	m
floatingse.member0_main_column:joint2	m
floatingse.memload0.s_full	m
floatingse.memload0.s_all
floatingse.memload0.g2e.Px_global	N/m
floatingse.memload0.g2e.Py_global	N/m
floatingse.memload0.g2e.Pz_global	N/m
floatingse.memload0.g2e.qdyn_global	Pa
floatingse.memload0.lc:Px	N/m
floatingse.memload0.lc:Py	N/m
floatingse.memload0.lc:Pz	N/m
floatingse.memload0.lc:qdyn	Pa
floatingse.memload1.env.distLoads.windLoads_Px	N/m
floatingse.memload1.env.distLoads.windLoads_Py	N/m
floatingse.memload1.env.distLoads.windLoads_Pz	N/m
floatingse.memload1.env.distLoads.windLoads_qdyn	N/m**2
floatingse.memload1.env.distLoads.windLoads_z	m
floatingse.memload1.env.distLoads.windLoads_beta	deg
floatingse.memload1.env.distLoads.waveLoads_Px	N/m
floatingse.memload1.env.distLoads.waveLoads_Py	N/m
floatingse.memload1.env.distLoads.waveLoads_Pz	N/m
floatingse.memload1.env.distLoads.waveLoads_qdyn	N/m**2
floatingse.memload1.env.distLoads.waveLoads_z	m
floatingse.memload1.env.distLoads.waveLoads_beta	deg
floatingse.memload1.z_global	m
floatingse.memload1.env.waveLoads.U	m/s
floatingse.memload1.env.waveLoads.A	m/s**2
floatingse.memload1.env.waveLoads.p	N/m**2
floatingse.memload1.outer_diameter_full	m
floatingse.memload1.ca_usr
floatingse.memload1.cd_usr
floatingse.memload1.env.windLoads.U	m/s
floatingse.member1_column1:joint1	m
floatingse.member1_column1:joint2	m
floatingse.memload1.s_full	m
floatingse.memload1.s_all
floatingse.memload1.g2e.Px_global	N/m
floatingse.memload1.g2e.Py_global	N/m
floatingse.memload1.g2e.Pz_global	N/m
floatingse.memload1.g2e.qdyn_global	Pa
floatingse.memload1.lc:Px	N/m
floatingse.memload1.lc:Py	N/m
floatingse.memload1.lc:Pz	N/m
floatingse.memload1.lc:qdyn	Pa
floatingse.memload2.env.distLoads.windLoads_Px	N/m
floatingse.memload2.env.distLoads.windLoads_Py	N/m
floatingse.memload2.env.distLoads.windLoads_Pz	N/m
floatingse.memload2.env.distLoads.windLoads_qdyn	N/m**2
floatingse.memload2.env.distLoads.windLoads_z	m
floatingse.memload2.env.distLoads.windLoads_beta	deg
floatingse.memload2.env.distLoads.waveLoads_Px	N/m
floatingse.memload2.env.distLoads.waveLoads_Py	N/m
floatingse.memload2.env.distLoads.waveLoads_Pz	N/m
floatingse.memload2.env.distLoads.waveLoads_qdyn	N/m**2
floatingse.memload2.env.distLoads.waveLoads_z	m
floatingse.memload2.env.distLoads.waveLoads_beta	deg
floatingse.memload2.z_global	m
floatingse.memload2.env.waveLoads.U	m/s
floatingse.memload2.env.waveLoads.A	m/s**2
floatingse.memload2.env.waveLoads.p	N/m**2
floatingse.memload2.outer_diameter_full	m
floatingse.memload2.ca_usr
floatingse.memload2.cd_usr
floatingse.memload2.env.windLoads.U	m/s
floatingse.member2_column2:joint1	m
floatingse.member2_column2:joint2	m
floatingse.memload2.s_full	m
floatingse.memload2.s_all
floatingse.memload2.g2e.Px_global	N/m
floatingse.memload2.g2e.Py_global	N/m
floatingse.memload2.g2e.Pz_global	N/m
floatingse.memload2.g2e.qdyn_global	Pa
floatingse.memload2.lc:Px	N/m
floatingse.memload2.lc:Py	N/m
floatingse.memload2.lc:Pz	N/m
floatingse.memload2.lc:qdyn	Pa
floatingse.memload3.env.distLoads.windLoads_Px	N/m
floatingse.memload3.env.distLoads.windLoads_Py	N/m
floatingse.memload3.env.distLoads.windLoads_Pz	N/m
floatingse.memload3.env.distLoads.windLoads_qdyn	N/m**2
floatingse.memload3.env.distLoads.windLoads_z	m
floatingse.memload3.env.distLoads.windLoads_beta	deg
floatingse.memload3.env.distLoads.waveLoads_Px	N/m
floatingse.memload3.env.distLoads.waveLoads_Py	N/m
floatingse.memload3.env.distLoads.waveLoads_Pz	N/m
floatingse.memload3.env.distLoads.waveLoads_qdyn	N/m**2
floatingse.memload3.env.distLoads.waveLoads_z	m
floatingse.memload3.env.distLoads.waveLoads_beta	deg
floatingse.memload3.z_global	m
floatingse.memload3.env.waveLoads.U	m/s
floatingse.memload3.env.waveLoads.A	m/s**2
floatingse.memload3.env.waveLoads.p	N/m**2
floatingse.memload3.outer_diameter_full	m
floatingse.memload3.ca_usr
floatingse.memload3.cd_usr
floatingse.memload3.env.windLoads.U	m/s
floatingse.member3_column3:joint1	m
floatingse.member3_column3:joint2	m
floatingse.memload3.s_full	m
floatingse.memload3.s_all
floatingse.memload3.g2e.Px_global	N/m
floatingse.memload3.g2e.Py_global	N/m
floatingse.memload3.g2e.Pz_global	N/m
floatingse.memload3.g2e.qdyn_global	Pa
floatingse.memload3.lc:Px	N/m
floatingse.memload3.lc:Py	N/m
floatingse.memload3.lc:Pz	N/m
floatingse.memload3.lc:qdyn	Pa
floatingse.memload4.env.distLoads.windLoads_Px	N/m
floatingse.memload4.env.distLoads.windLoads_Py	N/m
floatingse.memload4.env.distLoads.windLoads_Pz	N/m
floatingse.memload4.env.distLoads.windLoads_qdyn	N/m**2
floatingse.memload4.env.distLoads.windLoads_z	m
floatingse.memload4.env.distLoads.windLoads_beta	deg
floatingse.memload4.env.distLoads.waveLoads_Px	N/m
floatingse.memload4.env.distLoads.waveLoads_Py	N/m
floatingse.memload4.env.distLoads.waveLoads_Pz	N/m
floatingse.memload4.env.distLoads.waveLoads_qdyn	N/m**2
floatingse.memload4.env.distLoads.waveLoads_z	m
floatingse.memload4.env.distLoads.waveLoads_beta	deg
floatingse.memload4.z_global	m
floatingse.memload4.env.waveLoads.U	m/s
floatingse.memload4.env.waveLoads.A	m/s**2
floatingse.memload4.env.waveLoads.p	N/m**2
floatingse.memload4.outer_diameter_full	m
floatingse.memload4.ca_usr
floatingse.memload4.cd_usr
floatingse.memload4.env.windLoads.U	m/s
floatingse.member4_Y_pontoon_upper1:joint1	m
floatingse.member4_Y_pontoon_upper1:joint2	m
floatingse.memload4.s_full	m
floatingse.memload4.s_all
floatingse.memload4.g2e.Px_global	N/m
floatingse.memload4.g2e.Py_global	N/m
floatingse.memload4.g2e.Pz_global	N/m
floatingse.memload4.g2e.qdyn_global	Pa
floatingse.memload4.lc:Px	N/m
floatingse.memload4.lc:Py	N/m
floatingse.memload4.lc:Pz	N/m
floatingse.memload4.lc:qdyn	Pa
floatingse.memload5.env.distLoads.windLoads_Px	N/m
floatingse.memload5.env.distLoads.windLoads_Py	N/m
floatingse.memload5.env.distLoads.windLoads_Pz	N/m
floatingse.memload5.env.distLoads.windLoads_qdyn	N/m**2
floatingse.memload5.env.distLoads.windLoads_z	m
floatingse.memload5.env.distLoads.windLoads_beta	deg
floatingse.memload5.env.distLoads.waveLoads_Px	N/m
floatingse.memload5.env.distLoads.waveLoads_Py	N/m
floatingse.memload5.env.distLoads.waveLoads_Pz	N/m
floatingse.memload5.env.distLoads.waveLoads_qdyn	N/m**2
floatingse.memload5.env.distLoads.waveLoads_z	m
floatingse.memload5.env.distLoads.waveLoads_beta	deg
floatingse.memload5.z_global	m
floatingse.memload5.env.waveLoads.U	m/s
floatingse.memload5.env.waveLoads.A	m/s**2
floatingse.memload5.env.waveLoads.p	N/m**2
floatingse.memload5.outer_diameter_full	m
floatingse.memload5.ca_usr
floatingse.memload5.cd_usr
floatingse.memload5.env.windLoads.U	m/s
floatingse.member5_Y_pontoon_upper2:joint1	m
floatingse.member5_Y_pontoon_upper2:joint2	m
floatingse.memload5.s_full	m
floatingse.memload5.s_all
floatingse.memload5.g2e.Px_global	N/m
floatingse.memload5.g2e.Py_global	N/m
floatingse.memload5.g2e.Pz_global	N/m
floatingse.memload5.g2e.qdyn_global	Pa
floatingse.memload5.lc:Px	N/m
floatingse.memload5.lc:Py	N/m
floatingse.memload5.lc:Pz	N/m
floatingse.memload5.lc:qdyn	Pa
floatingse.memload6.env.distLoads.windLoads_Px	N/m
floatingse.memload6.env.distLoads.windLoads_Py	N/m
floatingse.memload6.env.distLoads.windLoads_Pz	N/m
floatingse.memload6.env.distLoads.windLoads_qdyn	N/m**2
floatingse.memload6.env.distLoads.windLoads_z	m
floatingse.memload6.env.distLoads.windLoads_beta	deg
floatingse.memload6.env.distLoads.waveLoads_Px	N/m
floatingse.memload6.env.distLoads.waveLoads_Py	N/m
floatingse.memload6.env.distLoads.waveLoads_Pz	N/m
floatingse.memload6.env.distLoads.waveLoads_qdyn	N/m**2
floatingse.memload6.env.distLoads.waveLoads_z	m
floatingse.memload6.env.distLoads.waveLoads_beta	deg
floatingse.memload6.z_global	m
floatingse.memload6.env.waveLoads.U	m/s
floatingse.memload6.env.waveLoads.A	m/s**2
floatingse.memload6.env.waveLoads.p	N/m**2
floatingse.memload6.outer_diameter_full	m
floatingse.memload6.ca_usr
floatingse.memload6.cd_usr
floatingse.memload6.env.windLoads.U	m/s
floatingse.member6_Y_pontoon_upper3:joint1	m
floatingse.member6_Y_pontoon_upper3:joint2	m
floatingse.memload6.s_full	m
floatingse.memload6.s_all
floatingse.memload6.g2e.Px_global	N/m
floatingse.memload6.g2e.Py_global	N/m
floatingse.memload6.g2e.Pz_global	N/m
floatingse.memload6.g2e.qdyn_global	Pa
floatingse.memload6.lc:Px	N/m
floatingse.memload6.lc:Py	N/m
floatingse.memload6.lc:Pz	N/m
floatingse.memload6.lc:qdyn	Pa
floatingse.memload7.env.distLoads.windLoads_Px	N/m
floatingse.memload7.env.distLoads.windLoads_Py	N/m
floatingse.memload7.env.distLoads.windLoads_Pz	N/m
floatingse.memload7.env.distLoads.windLoads_qdyn	N/m**2
floatingse.memload7.env.distLoads.windLoads_z	m
floatingse.memload7.env.distLoads.windLoads_beta	deg
floatingse.memload7.env.distLoads.waveLoads_Px	N/m
floatingse.memload7.env.distLoads.waveLoads_Py	N/m
floatingse.memload7.env.distLoads.waveLoads_Pz	N/m
floatingse.memload7.env.distLoads.waveLoads_qdyn	N/m**2
floatingse.memload7.env.distLoads.waveLoads_z	m
floatingse.memload7.env.distLoads.waveLoads_beta	deg
floatingse.memload7.z_global	m
floatingse.memload7.env.waveLoads.U	m/s
floatingse.memload7.env.waveLoads.A	m/s**2
floatingse.memload7.env.waveLoads.p	N/m**2
floatingse.memload7.outer_diameter_full	m
floatingse.memload7.ca_usr
floatingse.memload7.cd_usr
floatingse.memload7.env.windLoads.U	m/s
floatingse.member7_Y_pontoon_lower1:joint1	m
floatingse.member7_Y_pontoon_lower1:joint2	m
floatingse.memload7.s_full	m
floatingse.memload7.s_all
floatingse.memload7.g2e.Px_global	N/m
floatingse.memload7.g2e.Py_global	N/m
floatingse.memload7.g2e.Pz_global	N/m
floatingse.memload7.g2e.qdyn_global	Pa
floatingse.memload7.lc:Px	N/m
floatingse.memload7.lc:Py	N/m
floatingse.memload7.lc:Pz	N/m
floatingse.memload7.lc:qdyn	Pa
floatingse.memload8.env.distLoads.windLoads_Px	N/m
floatingse.memload8.env.distLoads.windLoads_Py	N/m
floatingse.memload8.env.distLoads.windLoads_Pz	N/m
floatingse.memload8.env.distLoads.windLoads_qdyn	N/m**2
floatingse.memload8.env.distLoads.windLoads_z	m
floatingse.memload8.env.distLoads.windLoads_beta	deg
floatingse.memload8.env.distLoads.waveLoads_Px	N/m
floatingse.memload8.env.distLoads.waveLoads_Py	N/m
floatingse.memload8.env.distLoads.waveLoads_Pz	N/m
floatingse.memload8.env.distLoads.waveLoads_qdyn	N/m**2
floatingse.memload8.env.distLoads.waveLoads_z	m
floatingse.memload8.env.distLoads.waveLoads_beta	deg
floatingse.memload8.z_global	m
floatingse.memload8.env.waveLoads.U	m/s
floatingse.memload8.env.waveLoads.A	m/s**2
floatingse.memload8.env.waveLoads.p	N/m**2
floatingse.memload8.outer_diameter_full	m
floatingse.memload8.ca_usr
floatingse.memload8.cd_usr
floatingse.memload8.env.windLoads.U	m/s
floatingse.member8_Y_pontoon_lower2:joint1	m
floatingse.member8_Y_pontoon_lower2:joint2	m
floatingse.memload8.s_full	m
floatingse.memload8.s_all
floatingse.memload8.g2e.Px_global	N/m
floatingse.memload8.g2e.Py_global	N/m
floatingse.memload8.g2e.Pz_global	N/m
floatingse.memload8.g2e.qdyn_global	Pa
floatingse.memload8.lc:Px	N/m
floatingse.memload8.lc:Py	N/m
floatingse.memload8.lc:Pz	N/m
floatingse.memload8.lc:qdyn	Pa
floatingse.memload9.env.distLoads.windLoads_Px	N/m
floatingse.memload9.env.distLoads.windLoads_Py	N/m
floatingse.memload9.env.distLoads.windLoads_Pz	N/m
floatingse.memload9.env.distLoads.windLoads_qdyn	N/m**2
floatingse.memload9.env.distLoads.windLoads_z	m
floatingse.memload9.env.distLoads.windLoads_beta	deg
floatingse.memload9.env.distLoads.waveLoads_Px	N/m
floatingse.memload9.env.distLoads.waveLoads_Py	N/m
floatingse.memload9.env.distLoads.waveLoads_Pz	N/m
floatingse.memload9.env.distLoads.waveLoads_qdyn	N/m**2
floatingse.memload9.env.distLoads.waveLoads_z	m
floatingse.memload9.env.distLoads.waveLoads_beta	deg
floatingse.memload9.z_global	m
floatingse.memload9.env.waveLoads.U	m/s
floatingse.memload9.env.waveLoads.A	m/s**2
floatingse.memload9.env.waveLoads.p	N/m**2
floatingse.memload9.outer_diameter_full	m
floatingse.memload9.ca_usr
floatingse.memload9.cd_usr
floatingse.memload9.env.windLoads.U	m/s
floatingse.member9_Y_pontoon_lower3:joint1	m
floatingse.member9_Y_pontoon_lower3:joint2	m
floatingse.memload9.s_full	m
floatingse.memload9.s_all
floatingse.memload9.g2e.Px_global	N/m
floatingse.memload9.g2e.Py_global	N/m
floatingse.memload9.g2e.Pz_global	N/m
floatingse.memload9.g2e.qdyn_global	Pa
floatingse.memload9.lc:Px	N/m
floatingse.memload9.lc:Py	N/m
floatingse.memload9.lc:Pz	N/m
floatingse.memload9.lc:qdyn	Pa
floatingse.platform_elem_D	m
floatingse.platform_elem_a	m
floatingse.platform_elem_b	m
floatingse.platform_elem_sigma_y	Pa
floatingse.platform_elem_qdyn	Pa
floatingse.platform_Fz	N
floatingse.platform_Vx	N
floatingse.platform_Vy	N
floatingse.platform_Mxx	N*m
floatingse.platform_Myy	N*m
floatingse.platform_Mzz	N*m
floatingse.tower_xyz	m
floatingse.tower_A	m**2
floatingse.tower_Asx	m**2
floatingse.tower_Asy	m**2
floatingse.tower_Ixx	kg*m**2
floatingse.tower_Iyy	kg*m**2
floatingse.tower_J0	kg*m**2
floatingse.tower_rho	kg/m**3
floatingse.tower_E	Pa
floatingse.tower_G	Pa
floatingse.rna_mass	kg
floatingse.rna_I	kg*m**2
floatingse.rna_cg	m
floatingse.platform_total_center_of_mass	m
floatingse.platform_I_total	kg*m**2
floatingse.platform_Awater	m**2
floatingse.system_mass	kg
floatingse.system_I	kg*m**2
floatingse.metacentric_height_roll	m
floatingse.metacentric_height_pitch	m
floatingse.platform_ballast_mass	kg
floatingse.platform_hull_mass	kg
floatingse.platform_I_hull	kg*m**2
floatingse.turbine_mass	kg
floatingse.turbine_cg	m
floatingse.turbine_I	kg*m**2
floatingse.platform_variable_capacity	m**3
floatingse.member0_main_column:variable_ballast_Vpts	m**3
floatingse.member0_main_column:variable_ballast_spts
floatingse.member1_column1:variable_ballast_Vpts	m**3
floatingse.member1_column1:variable_ballast_spts
floatingse.member2_column2:variable_ballast_Vpts	m**3
floatingse.member2_column2:variable_ballast_spts
floatingse.member3_column3:variable_ballast_Vpts	m**3
floatingse.member3_column3:variable_ballast_spts
floatingse.member4_Y_pontoon_upper1:variable_ballast_Vpts	m**3
floatingse.member4_Y_pontoon_upper1:variable_ballast_spts
floatingse.member5_Y_pontoon_upper2:variable_ballast_Vpts	m**3
floatingse.member5_Y_pontoon_upper2:variable_ballast_spts
floatingse.member6_Y_pontoon_upper3:variable_ballast_Vpts	m**3
floatingse.member6_Y_pontoon_upper3:variable_ballast_spts
floatingse.member7_Y_pontoon_lower1:variable_ballast_Vpts	m**3
floatingse.member7_Y_pontoon_lower1:variable_ballast_spts
floatingse.member8_Y_pontoon_lower2:variable_ballast_Vpts	m**3
floatingse.member8_Y_pontoon_lower2:variable_ballast_spts
floatingse.member9_Y_pontoon_lower3:variable_ballast_Vpts	m**3
floatingse.member9_Y_pontoon_lower3:variable_ballast_spts
floatingse.member0_main_column:nodes_r	m
floatingse.member0_main_column:section_D	m
floatingse.member0_main_column:Iwaterx	m**4
floatingse.member0_main_column:Iwatery	m**4
floatingse.member0_main_column:section_t	m
floatingse.member0_main_column:section_A	m**2
floatingse.member0_main_column:section_Asx	m**2
floatingse.member0_main_column:section_Asy	m**2
floatingse.member0_main_column:section_Ixx	kg*m**2
floatingse.member0_main_column:section_Iyy	kg*m**2
floatingse.member0_main_column:section_J0	kg*m**2
floatingse.member0_main_column:section_rho	kg/m**3
floatingse.member0_main_column:section_E	Pa
floatingse.member0_main_column:section_G	Pa
floatingse.member0_main_column:section_TorsC	m**3
floatingse.member0_main_column:section_sigma_y	Pa
floatingse.member0_main_column:idx_cb
floatingse.member0_main_column:buoyancy_force	N
floatingse.member0_main_column:displacement	m**3
floatingse.member0_main_column:center_of_buoyancy	m
floatingse.member0_main_column:center_of_mass	m
floatingse.member0_main_column:ballast_mass	kg
floatingse.member0_main_column:total_mass	kg
floatingse.member0_main_column:total_cost	USD
floatingse.member0_main_column:I_total	kg*m**2
floatingse.member0_main_column:Awater	m**2
floatingse.member0_main_column:added_mass	kg
floatingse.member0_main_column:waterline_centroid	m
floatingse.member0_main_column:variable_ballast_capacity	m**3
floatingse.member1_column1:nodes_r	m
floatingse.member1_column1:section_D	m
floatingse.member1_column1:Iwaterx	m**4
floatingse.member1_column1:Iwatery	m**4
floatingse.member1_column1:section_t	m
floatingse.member1_column1:section_A	m**2
floatingse.member1_column1:section_Asx	m**2
floatingse.member1_column1:section_Asy	m**2
floatingse.member1_column1:section_Ixx	kg*m**2
floatingse.member1_column1:section_Iyy	kg*m**2
floatingse.member1_column1:section_J0	kg*m**2
floatingse.member1_column1:section_rho	kg/m**3
floatingse.member1_column1:section_E	Pa
floatingse.member1_column1:section_G	Pa
floatingse.member1_column1:section_TorsC	m**3
floatingse.member1_column1:section_sigma_y	Pa
floatingse.member1_column1:idx_cb
floatingse.member1_column1:buoyancy_force	N
floatingse.member1_column1:displacement	m**3
floatingse.member1_column1:center_of_buoyancy	m
floatingse.member1_column1:center_of_mass	m
floatingse.member1_column1:ballast_mass	kg
floatingse.member1_column1:total_mass	kg
floatingse.member1_column1:total_cost	USD
floatingse.member1_column1:I_total	kg*m**2
floatingse.member1_column1:Awater	m**2
floatingse.member1_column1:added_mass	kg
floatingse.member1_column1:waterline_centroid	m
floatingse.member1_column1:variable_ballast_capacity	m**3
floatingse.member2_column2:nodes_r	m
floatingse.member2_column2:section_D	m
floatingse.member2_column2:Iwaterx	m**4
floatingse.member2_column2:Iwatery	m**4
floatingse.member2_column2:section_t	m
floatingse.member2_column2:section_A	m**2
floatingse.member2_column2:section_Asx	m**2
floatingse.member2_column2:section_Asy	m**2
floatingse.member2_column2:section_Ixx	kg*m**2
floatingse.member2_column2:section_Iyy	kg*m**2
floatingse.member2_column2:section_J0	kg*m**2
floatingse.member2_column2:section_rho	kg/m**3
floatingse.member2_column2:section_E	Pa
floatingse.member2_column2:section_G	Pa
floatingse.member2_column2:section_TorsC	m**3
floatingse.member2_column2:section_sigma_y	Pa
floatingse.member2_column2:idx_cb
floatingse.member2_column2:buoyancy_force	N
floatingse.member2_column2:displacement	m**3
floatingse.member2_column2:center_of_buoyancy	m
floatingse.member2_column2:center_of_mass	m
floatingse.member2_column2:ballast_mass	kg
floatingse.member2_column2:total_mass	kg
floatingse.member2_column2:total_cost	USD
floatingse.member2_column2:I_total	kg*m**2
floatingse.member2_column2:Awater	m**2
floatingse.member2_column2:added_mass	kg
floatingse.member2_column2:waterline_centroid	m
floatingse.member2_column2:variable_ballast_capacity	m**3
floatingse.member3_column3:nodes_r	m
floatingse.member3_column3:section_D	m
floatingse.member3_column3:Iwaterx	m**4
floatingse.member3_column3:Iwatery	m**4
floatingse.member3_column3:section_t	m
floatingse.member3_column3:section_A	m**2
floatingse.member3_column3:section_Asx	m**2
floatingse.member3_column3:section_Asy	m**2
floatingse.member3_column3:section_Ixx	kg*m**2
floatingse.member3_column3:section_Iyy	kg*m**2
floatingse.member3_column3:section_J0	kg*m**2
floatingse.member3_column3:section_rho	kg/m**3
floatingse.member3_column3:section_E	Pa
floatingse.member3_column3:section_G	Pa
floatingse.member3_column3:section_TorsC	m**3
floatingse.member3_column3:section_sigma_y	Pa
floatingse.member3_column3:idx_cb
floatingse.member3_column3:buoyancy_force	N
floatingse.member3_column3:displacement	m**3
floatingse.member3_column3:center_of_buoyancy	m
floatingse.member3_column3:center_of_mass	m
floatingse.member3_column3:ballast_mass	kg
floatingse.member3_column3:total_mass	kg
floatingse.member3_column3:total_cost	USD
floatingse.member3_column3:I_total	kg*m**2
floatingse.member3_column3:Awater	m**2
floatingse.member3_column3:added_mass	kg
floatingse.member3_column3:waterline_centroid	m
floatingse.member3_column3:variable_ballast_capacity	m**3
floatingse.member4_Y_pontoon_upper1:nodes_r	m
floatingse.member4_Y_pontoon_upper1:section_D	m
floatingse.member4_Y_pontoon_upper1:Iwaterx	m**4
floatingse.member4_Y_pontoon_upper1:Iwatery	m**4
floatingse.member4_Y_pontoon_upper1:section_t	m
floatingse.member4_Y_pontoon_upper1:section_A	m**2
floatingse.member4_Y_pontoon_upper1:section_Asx	m**2
floatingse.member4_Y_pontoon_upper1:section_Asy	m**2
floatingse.member4_Y_pontoon_upper1:section_Ixx	kg*m**2
floatingse.member4_Y_pontoon_upper1:section_Iyy	kg*m**2
floatingse.member4_Y_pontoon_upper1:section_J0	kg*m**2
floatingse.member4_Y_pontoon_upper1:section_rho	kg/m**3
floatingse.member4_Y_pontoon_upper1:section_E	Pa
floatingse.member4_Y_pontoon_upper1:section_G	Pa
floatingse.member4_Y_pontoon_upper1:section_TorsC	m**3
floatingse.member4_Y_pontoon_upper1:section_sigma_y	Pa
floatingse.member4_Y_pontoon_upper1:idx_cb
floatingse.member4_Y_pontoon_upper1:buoyancy_force	N
floatingse.member4_Y_pontoon_upper1:displacement	m**3
floatingse.member4_Y_pontoon_upper1:center_of_buoyancy	m
floatingse.member4_Y_pontoon_upper1:center_of_mass	m
floatingse.member4_Y_pontoon_upper1:ballast_mass	kg
floatingse.member4_Y_pontoon_upper1:total_mass	kg
floatingse.member4_Y_pontoon_upper1:total_cost	USD
floatingse.member4_Y_pontoon_upper1:I_total	kg*m**2
floatingse.member4_Y_pontoon_upper1:Awater	m**2
floatingse.member4_Y_pontoon_upper1:added_mass	kg
floatingse.member4_Y_pontoon_upper1:waterline_centroid	m
floatingse.member4_Y_pontoon_upper1:variable_ballast_capacity	m**3
floatingse.member5_Y_pontoon_upper2:nodes_r	m
floatingse.member5_Y_pontoon_upper2:section_D	m
floatingse.member5_Y_pontoon_upper2:Iwaterx	m**4
floatingse.member5_Y_pontoon_upper2:Iwatery	m**4
floatingse.member5_Y_pontoon_upper2:section_t	m
floatingse.member5_Y_pontoon_upper2:section_A	m**2
floatingse.member5_Y_pontoon_upper2:section_Asx	m**2
floatingse.member5_Y_pontoon_upper2:section_Asy	m**2
floatingse.member5_Y_pontoon_upper2:section_Ixx	kg*m**2
floatingse.member5_Y_pontoon_upper2:section_Iyy	kg*m**2
floatingse.member5_Y_pontoon_upper2:section_J0	kg*m**2
floatingse.member5_Y_pontoon_upper2:section_rho	kg/m**3
floatingse.member5_Y_pontoon_upper2:section_E	Pa
floatingse.member5_Y_pontoon_upper2:section_G	Pa
floatingse.member5_Y_pontoon_upper2:section_TorsC	m**3
floatingse.member5_Y_pontoon_upper2:section_sigma_y	Pa
floatingse.member5_Y_pontoon_upper2:idx_cb
floatingse.member5_Y_pontoon_upper2:buoyancy_force	N
floatingse.member5_Y_pontoon_upper2:displacement	m**3
floatingse.member5_Y_pontoon_upper2:center_of_buoyancy	m
floatingse.member5_Y_pontoon_upper2:center_of_mass	m
floatingse.member5_Y_pontoon_upper2:ballast_mass	kg
floatingse.member5_Y_pontoon_upper2:total_mass	kg
floatingse.member5_Y_pontoon_upper2:total_cost	USD
floatingse.member5_Y_pontoon_upper2:I_total	kg*m**2
floatingse.member5_Y_pontoon_upper2:Awater	m**2
floatingse.member5_Y_pontoon_upper2:added_mass	kg
floatingse.member5_Y_pontoon_upper2:waterline_centroid	m
floatingse.member5_Y_pontoon_upper2:variable_ballast_capacity	m**3
floatingse.member6_Y_pontoon_upper3:nodes_r	m
floatingse.member6_Y_pontoon_upper3:section_D	m
floatingse.member6_Y_pontoon_upper3:Iwaterx	m**4
floatingse.member6_Y_pontoon_upper3:Iwatery	m**4
floatingse.member6_Y_pontoon_upper3:section_t	m
floatingse.member6_Y_pontoon_upper3:section_A	m**2
floatingse.member6_Y_pontoon_upper3:section_Asx	m**2
floatingse.member6_Y_pontoon_upper3:section_Asy	m**2
floatingse.member6_Y_pontoon_upper3:section_Ixx	kg*m**2
floatingse.member6_Y_pontoon_upper3:section_Iyy	kg*m**2
floatingse.member6_Y_pontoon_upper3:section_J0	kg*m**2
floatingse.member6_Y_pontoon_upper3:section_rho	kg/m**3
floatingse.member6_Y_pontoon_upper3:section_E	Pa
floatingse.member6_Y_pontoon_upper3:section_G	Pa
floatingse.member6_Y_pontoon_upper3:section_TorsC	m**3
floatingse.member6_Y_pontoon_upper3:section_sigma_y	Pa
floatingse.member6_Y_pontoon_upper3:idx_cb
floatingse.member6_Y_pontoon_upper3:buoyancy_force	N
floatingse.member6_Y_pontoon_upper3:displacement	m**3
floatingse.member6_Y_pontoon_upper3:center_of_buoyancy	m
floatingse.member6_Y_pontoon_upper3:center_of_mass	m
floatingse.member6_Y_pontoon_upper3:ballast_mass	kg
floatingse.member6_Y_pontoon_upper3:total_mass	kg
floatingse.member6_Y_pontoon_upper3:total_cost	USD
floatingse.member6_Y_pontoon_upper3:I_total	kg*m**2
floatingse.member6_Y_pontoon_upper3:Awater	m**2
floatingse.member6_Y_pontoon_upper3:added_mass	kg
floatingse.member6_Y_pontoon_upper3:waterline_centroid	m
floatingse.member6_Y_pontoon_upper3:variable_ballast_capacity	m**3
floatingse.member7_Y_pontoon_lower1:nodes_r	m
floatingse.member7_Y_pontoon_lower1:section_D	m
floatingse.member7_Y_pontoon_lower1:Iwaterx	m**4
floatingse.member7_Y_pontoon_lower1:Iwatery	m**4
floatingse.member7_Y_pontoon_lower1:section_t	m
floatingse.member7_Y_pontoon_lower1:section_A	m**2
floatingse.member7_Y_pontoon_lower1:section_Asx	m**2
floatingse.member7_Y_pontoon_lower1:section_Asy	m**2
floatingse.member7_Y_pontoon_lower1:section_Ixx	kg*m**2
floatingse.member7_Y_pontoon_lower1:section_Iyy	kg*m**2
floatingse.member7_Y_pontoon_lower1:section_J0	kg*m**2
floatingse.member7_Y_pontoon_lower1:section_rho	kg/m**3
floatingse.member7_Y_pontoon_lower1:section_E	Pa
floatingse.member7_Y_pontoon_lower1:section_G	Pa
floatingse.member7_Y_pontoon_lower1:section_TorsC	m**3
floatingse.member7_Y_pontoon_lower1:section_sigma_y	Pa
floatingse.member7_Y_pontoon_lower1:idx_cb
floatingse.member7_Y_pontoon_lower1:buoyancy_force	N
floatingse.member7_Y_pontoon_lower1:displacement	m**3
floatingse.member7_Y_pontoon_lower1:center_of_buoyancy	m
floatingse.member7_Y_pontoon_lower1:center_of_mass	m
floatingse.member7_Y_pontoon_lower1:ballast_mass	kg
floatingse.member7_Y_pontoon_lower1:total_mass	kg
floatingse.member7_Y_pontoon_lower1:total_cost	USD
floatingse.member7_Y_pontoon_lower1:I_total	kg*m**2
floatingse.member7_Y_pontoon_lower1:Awater	m**2
floatingse.member7_Y_pontoon_lower1:added_mass	kg
floatingse.member7_Y_pontoon_lower1:waterline_centroid	m
floatingse.member7_Y_pontoon_lower1:variable_ballast_capacity	m**3
floatingse.member8_Y_pontoon_lower2:nodes_r	m
floatingse.member8_Y_pontoon_lower2:section_D	m
floatingse.member8_Y_pontoon_lower2:Iwaterx	m**4
floatingse.member8_Y_pontoon_lower2:Iwatery	m**4
floatingse.member8_Y_pontoon_lower2:section_t	m
floatingse.member8_Y_pontoon_lower2:section_A	m**2
floatingse.member8_Y_pontoon_lower2:section_Asx	m**2
floatingse.member8_Y_pontoon_lower2:section_Asy	m**2
floatingse.member8_Y_pontoon_lower2:section_Ixx	kg*m**2
floatingse.member8_Y_pontoon_lower2:section_Iyy	kg*m**2
floatingse.member8_Y_pontoon_lower2:section_J0	kg*m**2
floatingse.member8_Y_pontoon_lower2:section_rho	kg/m**3
floatingse.member8_Y_pontoon_lower2:section_E	Pa
floatingse.member8_Y_pontoon_lower2:section_G	Pa
floatingse.member8_Y_pontoon_lower2:section_TorsC	m**3
floatingse.member8_Y_pontoon_lower2:section_sigma_y	Pa
floatingse.member8_Y_pontoon_lower2:idx_cb
floatingse.member8_Y_pontoon_lower2:buoyancy_force	N
floatingse.member8_Y_pontoon_lower2:displacement	m**3
floatingse.member8_Y_pontoon_lower2:center_of_buoyancy	m
floatingse.member8_Y_pontoon_lower2:center_of_mass	m
floatingse.member8_Y_pontoon_lower2:ballast_mass	kg
floatingse.member8_Y_pontoon_lower2:total_mass	kg
floatingse.member8_Y_pontoon_lower2:total_cost	USD
floatingse.member8_Y_pontoon_lower2:I_total	kg*m**2
floatingse.member8_Y_pontoon_lower2:Awater	m**2
floatingse.member8_Y_pontoon_lower2:added_mass	kg
floatingse.member8_Y_pontoon_lower2:waterline_centroid	m
floatingse.member8_Y_pontoon_lower2:variable_ballast_capacity	m**3
floatingse.member9_Y_pontoon_lower3:nodes_r	m
floatingse.member9_Y_pontoon_lower3:section_D	m
floatingse.member9_Y_pontoon_lower3:Iwaterx	m**4
floatingse.member9_Y_pontoon_lower3:Iwatery	m**4
floatingse.member9_Y_pontoon_lower3:section_t	m
floatingse.member9_Y_pontoon_lower3:section_A	m**2
floatingse.member9_Y_pontoon_lower3:section_Asx	m**2
floatingse.member9_Y_pontoon_lower3:section_Asy	m**2
floatingse.member9_Y_pontoon_lower3:section_Ixx	kg*m**2
floatingse.member9_Y_pontoon_lower3:section_Iyy	kg*m**2
floatingse.member9_Y_pontoon_lower3:section_J0	kg*m**2
floatingse.member9_Y_pontoon_lower3:section_rho	kg/m**3
floatingse.member9_Y_pontoon_lower3:section_E	Pa
floatingse.member9_Y_pontoon_lower3:section_G	Pa
floatingse.member9_Y_pontoon_lower3:section_TorsC	m**3
floatingse.member9_Y_pontoon_lower3:section_sigma_y	Pa
floatingse.member9_Y_pontoon_lower3:idx_cb
floatingse.member9_Y_pontoon_lower3:buoyancy_force	N
floatingse.member9_Y_pontoon_lower3:displacement	m**3
floatingse.member9_Y_pontoon_lower3:center_of_buoyancy	m
floatingse.member9_Y_pontoon_lower3:center_of_mass	m
floatingse.member9_Y_pontoon_lower3:ballast_mass	kg
floatingse.member9_Y_pontoon_lower3:total_mass	kg
floatingse.member9_Y_pontoon_lower3:total_cost	USD
floatingse.member9_Y_pontoon_lower3:I_total	kg*m**2
floatingse.member9_Y_pontoon_lower3:Awater	m**2
floatingse.member9_Y_pontoon_lower3:added_mass	kg
floatingse.member9_Y_pontoon_lower3:waterline_centroid	m
floatingse.member9_Y_pontoon_lower3:variable_ballast_capacity	m**3
floatingse.transition_piece_cost	USD
floatingse.member0_main_column.gc.d	m
floatingse.member0_main_column.gc.t	m
floatingse.member0_main_column.s
floatingse.member0_main_column.height	m
floatingse.member0_main_column.outer_diameter	m
floatingse.member0_main_column.ca_usr_grid
floatingse.member0_main_column.cd_usr_grid
floatingse.member0_main_column.wall_thickness	m
floatingse.member0_main_column.E	Pa
floatingse.member0_main_column.G	Pa
floatingse.member0_main_column.sigma_y	Pa
floatingse.member0_main_column.rho	kg/m**3
floatingse.member0_main_column.unit_cost	USD/kg
floatingse.member0_main_column.outfitting_factor
floatingse.member0_main_column.nodes_xyz	m
floatingse.member0_main_column.s_full	m
floatingse.member0_main_column.z_full	m
floatingse.member0_main_column.outer_diameter_full	m
floatingse.member0_main_column.s_ghost1
floatingse.member0_main_column.s_ghost2
floatingse.member0_main_column.s_in
floatingse.member0_main_column.s_const1
floatingse.member0_main_column.s_const2
floatingse.member0_main_column.layer_thickness	m
floatingse.member0_main_column.outer_diameter_in	m
floatingse.E_mat	Pa
floatingse.member0_main_column.E_user	Pa
floatingse.G_mat	Pa
floatingse.sigma_y_mat	Pa
floatingse.sigma_ult_mat	Pa
floatingse.wohler_exp_mat
floatingse.wohler_A_mat
floatingse.rho_mat	kg/m**3
floatingse.unit_cost_mat	USD/kg
floatingse.member0_main_column.outfitting_factor_in
floatingse.member0_main_column.layer_materials	n/a
floatingse.member0_main_column.ballast_materials	n/a
floatingse.material_names	n/a
floatingse.member0_main_column.t_full	m
floatingse.member0_main_column.E_full	Pa
floatingse.member0_main_column.G_full	Pa
floatingse.member0_main_column.rho_full	kg/m**3
floatingse.member0_main_column.sigma_y_full	Pa
floatingse.member0_main_column.unit_cost_full	USD/kg
floatingse.member0_main_column.outfitting_full
floatingse.labor_cost_rate	USD/min
floatingse.painting_cost_rate	USD/m**2
floatingse.member0_main_column.grid_axial_joints
floatingse.member0_main_column.bulkhead_grid
floatingse.member0_main_column.bulkhead_thickness	m
floatingse.member0_main_column.ring_stiffener_web_height	m
floatingse.member0_main_column.ring_stiffener_web_thickness	m
floatingse.member0_main_column.ring_stiffener_flange_width	m
floatingse.member0_main_column.ring_stiffener_flange_thickness	m
floatingse.member0_main_column.ring_stiffener_spacing
floatingse.member0_main_column.axial_stiffener_web_height	m
floatingse.member0_main_column.axial_stiffener_web_thickness	m
floatingse.member0_main_column.axial_stiffener_flange_width	m
floatingse.member0_main_column.axial_stiffener_flange_thickness	m
floatingse.member0_main_column.axial_stiffener_spacing	rad
floatingse.member0_main_column.ballast_grid
floatingse.member0_main_column.ballast_density	kg/m**3
floatingse.member0_main_column.ballast_volume	m**3
floatingse.member0_main_column.ballast_unit_cost	USD/kg
floatingse.member0_main_column:mass_user	kg
floatingse.member1_column1.gc.d	m
floatingse.member1_column1.gc.t	m
floatingse.member1_column1.s
floatingse.member1_column1.height	m
floatingse.member1_column1.outer_diameter	m
floatingse.member1_column1.ca_usr_grid
floatingse.member1_column1.cd_usr_grid
floatingse.member1_column1.wall_thickness	m
floatingse.member1_column1.E	Pa
floatingse.member1_column1.G	Pa
floatingse.member1_column1.sigma_y	Pa
floatingse.member1_column1.rho	kg/m**3
floatingse.member1_column1.unit_cost	USD/kg
floatingse.member1_column1.outfitting_factor
floatingse.member1_column1.nodes_xyz	m
floatingse.member1_column1.s_full	m
floatingse.member1_column1.z_full	m
floatingse.member1_column1.outer_diameter_full	m
floatingse.member1_column1.s_ghost1
floatingse.member1_column1.s_ghost2
floatingse.member1_column1.s_in
floatingse.member1_column1.s_const1
floatingse.member1_column1.s_const2
floatingse.member1_column1.layer_thickness	m
floatingse.member1_column1.outer_diameter_in	m
floatingse.member1_column1.E_user	Pa
floatingse.member1_column1.outfitting_factor_in
floatingse.member1_column1.layer_materials	n/a
floatingse.member1_column1.ballast_materials	n/a
floatingse.member1_column1.t_full	m
floatingse.member1_column1.E_full	Pa
floatingse.member1_column1.G_full	Pa
floatingse.member1_column1.rho_full	kg/m**3
floatingse.member1_column1.sigma_y_full	Pa
floatingse.member1_column1.unit_cost_full	USD/kg
floatingse.member1_column1.outfitting_full
floatingse.member1_column1.grid_axial_joints
floatingse.member1_column1.bulkhead_grid
floatingse.member1_column1.bulkhead_thickness	m
floatingse.member1_column1.ring_stiffener_web_height	m
floatingse.member1_column1.ring_stiffener_web_thickness	m
floatingse.member1_column1.ring_stiffener_flange_width	m
floatingse.member1_column1.ring_stiffener_flange_thickness	m
floatingse.member1_column1.ring_stiffener_spacing
floatingse.member1_column1.axial_stiffener_web_height	m
floatingse.member1_column1.axial_stiffener_web_thickness	m
floatingse.member1_column1.axial_stiffener_flange_width	m
floatingse.member1_column1.axial_stiffener_flange_thickness	m
floatingse.member1_column1.axial_stiffener_spacing	rad
floatingse.member1_column1.ballast_grid
floatingse.member1_column1.ballast_density	kg/m**3
floatingse.member1_column1.ballast_volume	m**3
floatingse.member1_column1.ballast_unit_cost	USD/kg
floatingse.member1_column1:mass_user	kg
floatingse.member2_column2.gc.d	m
floatingse.member2_column2.gc.t	m
floatingse.member2_column2.s
floatingse.member2_column2.height	m
floatingse.member2_column2.outer_diameter	m
floatingse.member2_column2.ca_usr_grid
floatingse.member2_column2.cd_usr_grid
floatingse.member2_column2.wall_thickness	m
floatingse.member2_column2.E	Pa
floatingse.member2_column2.G	Pa
floatingse.member2_column2.sigma_y	Pa
floatingse.member2_column2.rho	kg/m**3
floatingse.member2_column2.unit_cost	USD/kg
floatingse.member2_column2.outfitting_factor
floatingse.member2_column2.nodes_xyz	m
floatingse.member2_column2.s_full	m
floatingse.member2_column2.z_full	m
floatingse.member2_column2.outer_diameter_full	m
floatingse.member2_column2.s_ghost1
floatingse.member2_column2.s_ghost2
floatingse.member2_column2.s_in
floatingse.member2_column2.s_const1
floatingse.member2_column2.s_const2
floatingse.member2_column2.layer_thickness	m
floatingse.member2_column2.outer_diameter_in	m
floatingse.member2_column2.E_user	Pa
floatingse.member2_column2.outfitting_factor_in
floatingse.member2_column2.layer_materials	n/a
floatingse.member2_column2.ballast_materials	n/a
floatingse.member2_column2.t_full	m
floatingse.member2_column2.E_full	Pa
floatingse.member2_column2.G_full	Pa
floatingse.member2_column2.rho_full	kg/m**3
floatingse.member2_column2.sigma_y_full	Pa
floatingse.member2_column2.unit_cost_full	USD/kg
floatingse.member2_column2.outfitting_full
floatingse.member2_column2.grid_axial_joints
floatingse.member2_column2.bulkhead_grid
floatingse.member2_column2.bulkhead_thickness	m
floatingse.member2_column2.ring_stiffener_web_height	m
floatingse.member2_column2.ring_stiffener_web_thickness	m
floatingse.member2_column2.ring_stiffener_flange_width	m
floatingse.member2_column2.ring_stiffener_flange_thickness	m
floatingse.member2_column2.ring_stiffener_spacing
floatingse.member2_column2.axial_stiffener_web_height	m
floatingse.member2_column2.axial_stiffener_web_thickness	m
floatingse.member2_column2.axial_stiffener_flange_width	m
floatingse.member2_column2.axial_stiffener_flange_thickness	m
floatingse.member2_column2.axial_stiffener_spacing	rad
floatingse.member2_column2.ballast_grid
floatingse.member2_column2.ballast_density	kg/m**3
floatingse.member2_column2.ballast_volume	m**3
floatingse.member2_column2.ballast_unit_cost	USD/kg
floatingse.member2_column2:mass_user	kg
floatingse.member3_column3.gc.d	m
floatingse.member3_column3.gc.t	m
floatingse.member3_column3.s
floatingse.member3_column3.height	m
floatingse.member3_column3.outer_diameter	m
floatingse.member3_column3.ca_usr_grid
floatingse.member3_column3.cd_usr_grid
floatingse.member3_column3.wall_thickness	m
floatingse.member3_column3.E	Pa
floatingse.member3_column3.G	Pa
floatingse.member3_column3.sigma_y	Pa
floatingse.member3_column3.rho	kg/m**3
floatingse.member3_column3.unit_cost	USD/kg
floatingse.member3_column3.outfitting_factor
floatingse.member3_column3.nodes_xyz	m
floatingse.member3_column3.s_full	m
floatingse.member3_column3.z_full	m
floatingse.member3_column3.outer_diameter_full	m
floatingse.member3_column3.s_ghost1
floatingse.member3_column3.s_ghost2
floatingse.member3_column3.s_in
floatingse.member3_column3.s_const1
floatingse.member3_column3.s_const2
floatingse.member3_column3.layer_thickness	m
floatingse.member3_column3.outer_diameter_in	m
floatingse.member3_column3.E_user	Pa
floatingse.member3_column3.outfitting_factor_in
floatingse.member3_column3.layer_materials	n/a
floatingse.member3_column3.ballast_materials	n/a
floatingse.member3_column3.t_full	m
floatingse.member3_column3.E_full	Pa
floatingse.member3_column3.G_full	Pa
floatingse.member3_column3.rho_full	kg/m**3
floatingse.member3_column3.sigma_y_full	Pa
floatingse.member3_column3.unit_cost_full	USD/kg
floatingse.member3_column3.outfitting_full
floatingse.member3_column3.grid_axial_joints
floatingse.member3_column3.bulkhead_grid
floatingse.member3_column3.bulkhead_thickness	m
floatingse.member3_column3.ring_stiffener_web_height	m
floatingse.member3_column3.ring_stiffener_web_thickness	m
floatingse.member3_column3.ring_stiffener_flange_width	m
floatingse.member3_column3.ring_stiffener_flange_thickness	m
floatingse.member3_column3.ring_stiffener_spacing
floatingse.member3_column3.axial_stiffener_web_height	m
floatingse.member3_column3.axial_stiffener_web_thickness	m
floatingse.member3_column3.axial_stiffener_flange_width	m
floatingse.member3_column3.axial_stiffener_flange_thickness	m
floatingse.member3_column3.axial_stiffener_spacing	rad
floatingse.member3_column3.ballast_grid
floatingse.member3_column3.ballast_density	kg/m**3
floatingse.member3_column3.ballast_volume	m**3
floatingse.member3_column3.ballast_unit_cost	USD/kg
floatingse.member3_column3:mass_user	kg
floatingse.member4_Y_pontoon_upper1.gc.d	m
floatingse.member4_Y_pontoon_upper1.gc.t	m
floatingse.member4_Y_pontoon_upper1.s
floatingse.member4_Y_pontoon_upper1.height	m
floatingse.member4_Y_pontoon_upper1.outer_diameter	m
floatingse.member4_Y_pontoon_upper1.ca_usr_grid
floatingse.member4_Y_pontoon_upper1.cd_usr_grid
floatingse.member4_Y_pontoon_upper1.wall_thickness	m
floatingse.member4_Y_pontoon_upper1.E	Pa
floatingse.member4_Y_pontoon_upper1.G	Pa
floatingse.member4_Y_pontoon_upper1.sigma_y	Pa
floatingse.member4_Y_pontoon_upper1.rho	kg/m**3
floatingse.member4_Y_pontoon_upper1.unit_cost	USD/kg
floatingse.member4_Y_pontoon_upper1.outfitting_factor
floatingse.member4_Y_pontoon_upper1.nodes_xyz	m
floatingse.member4_Y_pontoon_upper1.s_full	m
floatingse.member4_Y_pontoon_upper1.z_full	m
floatingse.member4_Y_pontoon_upper1.outer_diameter_full	m
floatingse.member4_Y_pontoon_upper1.s_ghost1
floatingse.member4_Y_pontoon_upper1.s_ghost2
floatingse.member4_Y_pontoon_upper1.s_in
floatingse.member4_Y_pontoon_upper1.s_const1
floatingse.member4_Y_pontoon_upper1.s_const2
floatingse.member4_Y_pontoon_upper1.layer_thickness	m
floatingse.member4_Y_pontoon_upper1.outer_diameter_in	m
floatingse.member4_Y_pontoon_upper1.E_user	Pa
floatingse.member4_Y_pontoon_upper1.outfitting_factor_in
floatingse.member4_Y_pontoon_upper1.layer_materials	n/a
floatingse.member4_Y_pontoon_upper1.ballast_materials	n/a
floatingse.member4_Y_pontoon_upper1.t_full	m
floatingse.member4_Y_pontoon_upper1.E_full	Pa
floatingse.member4_Y_pontoon_upper1.G_full	Pa
floatingse.member4_Y_pontoon_upper1.rho_full	kg/m**3
floatingse.member4_Y_pontoon_upper1.sigma_y_full	Pa
floatingse.member4_Y_pontoon_upper1.unit_cost_full	USD/kg
floatingse.member4_Y_pontoon_upper1.outfitting_full
floatingse.member4_Y_pontoon_upper1.grid_axial_joints
floatingse.member4_Y_pontoon_upper1.bulkhead_grid
floatingse.member4_Y_pontoon_upper1.bulkhead_thickness	m
floatingse.member4_Y_pontoon_upper1.ring_stiffener_web_height	m
floatingse.member4_Y_pontoon_upper1.ring_stiffener_web_thickness	m
floatingse.member4_Y_pontoon_upper1.ring_stiffener_flange_width	m
floatingse.member4_Y_pontoon_upper1.ring_stiffener_flange_thickness	m
floatingse.member4_Y_pontoon_upper1.ring_stiffener_spacing
floatingse.member4_Y_pontoon_upper1.axial_stiffener_web_height	m
floatingse.member4_Y_pontoon_upper1.axial_stiffener_web_thickness	m
floatingse.member4_Y_pontoon_upper1.axial_stiffener_flange_width	m
floatingse.member4_Y_pontoon_upper1.axial_stiffener_flange_thickness	m
floatingse.member4_Y_pontoon_upper1.axial_stiffener_spacing	rad
floatingse.member4_Y_pontoon_upper1.ballast_grid
floatingse.member4_Y_pontoon_upper1.ballast_density	kg/m**3
floatingse.member4_Y_pontoon_upper1.ballast_volume	m**3
floatingse.member4_Y_pontoon_upper1.ballast_unit_cost	USD/kg
floatingse.member4_Y_pontoon_upper1:mass_user	kg
floatingse.member5_Y_pontoon_upper2.gc.d	m
floatingse.member5_Y_pontoon_upper2.gc.t	m
floatingse.member5_Y_pontoon_upper2.s
floatingse.member5_Y_pontoon_upper2.height	m
floatingse.member5_Y_pontoon_upper2.outer_diameter	m
floatingse.member5_Y_pontoon_upper2.ca_usr_grid
floatingse.member5_Y_pontoon_upper2.cd_usr_grid
floatingse.member5_Y_pontoon_upper2.wall_thickness	m
floatingse.member5_Y_pontoon_upper2.E	Pa
floatingse.member5_Y_pontoon_upper2.G	Pa
floatingse.member5_Y_pontoon_upper2.sigma_y	Pa
floatingse.member5_Y_pontoon_upper2.rho	kg/m**3
floatingse.member5_Y_pontoon_upper2.unit_cost	USD/kg
floatingse.member5_Y_pontoon_upper2.outfitting_factor
floatingse.member5_Y_pontoon_upper2.nodes_xyz	m
floatingse.member5_Y_pontoon_upper2.s_full	m
floatingse.member5_Y_pontoon_upper2.z_full	m
floatingse.member5_Y_pontoon_upper2.outer_diameter_full	m
floatingse.member5_Y_pontoon_upper2.s_ghost1
floatingse.member5_Y_pontoon_upper2.s_ghost2
floatingse.member5_Y_pontoon_upper2.s_in
floatingse.member5_Y_pontoon_upper2.s_const1
floatingse.member5_Y_pontoon_upper2.s_const2
floatingse.member5_Y_pontoon_upper2.layer_thickness	m
floatingse.member5_Y_pontoon_upper2.outer_diameter_in	m
floatingse.member5_Y_pontoon_upper2.E_user	Pa
floatingse.member5_Y_pontoon_upper2.outfitting_factor_in
floatingse.member5_Y_pontoon_upper2.layer_materials	n/a
floatingse.member5_Y_pontoon_upper2.ballast_materials	n/a
floatingse.member5_Y_pontoon_upper2.t_full	m
floatingse.member5_Y_pontoon_upper2.E_full	Pa
floatingse.member5_Y_pontoon_upper2.G_full	Pa
floatingse.member5_Y_pontoon_upper2.rho_full	kg/m**3
floatingse.member5_Y_pontoon_upper2.sigma_y_full	Pa
floatingse.member5_Y_pontoon_upper2.unit_cost_full	USD/kg
floatingse.member5_Y_pontoon_upper2.outfitting_full
floatingse.member5_Y_pontoon_upper2.grid_axial_joints
floatingse.member5_Y_pontoon_upper2.bulkhead_grid
floatingse.member5_Y_pontoon_upper2.bulkhead_thickness	m
floatingse.member5_Y_pontoon_upper2.ring_stiffener_web_height	m
floatingse.member5_Y_pontoon_upper2.ring_stiffener_web_thickness	m
floatingse.member5_Y_pontoon_upper2.ring_stiffener_flange_width	m
floatingse.member5_Y_pontoon_upper2.ring_stiffener_flange_thickness	m
floatingse.member5_Y_pontoon_upper2.ring_stiffener_spacing
floatingse.member5_Y_pontoon_upper2.axial_stiffener_web_height	m
floatingse.member5_Y_pontoon_upper2.axial_stiffener_web_thickness	m
floatingse.member5_Y_pontoon_upper2.axial_stiffener_flange_width	m
floatingse.member5_Y_pontoon_upper2.axial_stiffener_flange_thickness	m
floatingse.member5_Y_pontoon_upper2.axial_stiffener_spacing	rad
floatingse.member5_Y_pontoon_upper2.ballast_grid
floatingse.member5_Y_pontoon_upper2.ballast_density	kg/m**3
floatingse.member5_Y_pontoon_upper2.ballast_volume	m**3
floatingse.member5_Y_pontoon_upper2.ballast_unit_cost	USD/kg
floatingse.member5_Y_pontoon_upper2:mass_user	kg
floatingse.member6_Y_pontoon_upper3.gc.d	m
floatingse.member6_Y_pontoon_upper3.gc.t	m
floatingse.member6_Y_pontoon_upper3.s
floatingse.member6_Y_pontoon_upper3.height	m
floatingse.member6_Y_pontoon_upper3.outer_diameter	m
floatingse.member6_Y_pontoon_upper3.ca_usr_grid
floatingse.member6_Y_pontoon_upper3.cd_usr_grid
floatingse.member6_Y_pontoon_upper3.wall_thickness	m
floatingse.member6_Y_pontoon_upper3.E	Pa
floatingse.member6_Y_pontoon_upper3.G	Pa
floatingse.member6_Y_pontoon_upper3.sigma_y	Pa
floatingse.member6_Y_pontoon_upper3.rho	kg/m**3
floatingse.member6_Y_pontoon_upper3.unit_cost	USD/kg
floatingse.member6_Y_pontoon_upper3.outfitting_factor
floatingse.member6_Y_pontoon_upper3.nodes_xyz	m
floatingse.member6_Y_pontoon_upper3.s_full	m
floatingse.member6_Y_pontoon_upper3.z_full	m
floatingse.member6_Y_pontoon_upper3.outer_diameter_full	m
floatingse.member6_Y_pontoon_upper3.s_ghost1
floatingse.member6_Y_pontoon_upper3.s_ghost2
floatingse.member6_Y_pontoon_upper3.s_in
floatingse.member6_Y_pontoon_upper3.s_const1
floatingse.member6_Y_pontoon_upper3.s_const2
floatingse.member6_Y_pontoon_upper3.layer_thickness	m
floatingse.member6_Y_pontoon_upper3.outer_diameter_in	m
floatingse.member6_Y_pontoon_upper3.E_user	Pa
floatingse.member6_Y_pontoon_upper3.outfitting_factor_in
floatingse.member6_Y_pontoon_upper3.layer_materials	n/a
floatingse.member6_Y_pontoon_upper3.ballast_materials	n/a
floatingse.member6_Y_pontoon_upper3.t_full	m
floatingse.member6_Y_pontoon_upper3.E_full	Pa
floatingse.member6_Y_pontoon_upper3.G_full	Pa
floatingse.member6_Y_pontoon_upper3.rho_full	kg/m**3
floatingse.member6_Y_pontoon_upper3.sigma_y_full	Pa
floatingse.member6_Y_pontoon_upper3.unit_cost_full	USD/kg
floatingse.member6_Y_pontoon_upper3.outfitting_full
floatingse.member6_Y_pontoon_upper3.grid_axial_joints
floatingse.member6_Y_pontoon_upper3.bulkhead_grid
floatingse.member6_Y_pontoon_upper3.bulkhead_thickness	m
floatingse.member6_Y_pontoon_upper3.ring_stiffener_web_height	m
floatingse.member6_Y_pontoon_upper3.ring_stiffener_web_thickness	m
floatingse.member6_Y_pontoon_upper3.ring_stiffener_flange_width	m
floatingse.member6_Y_pontoon_upper3.ring_stiffener_flange_thickness	m
floatingse.member6_Y_pontoon_upper3.ring_stiffener_spacing
floatingse.member6_Y_pontoon_upper3.axial_stiffener_web_height	m
floatingse.member6_Y_pontoon_upper3.axial_stiffener_web_thickness	m
floatingse.member6_Y_pontoon_upper3.axial_stiffener_flange_width	m
floatingse.member6_Y_pontoon_upper3.axial_stiffener_flange_thickness	m
floatingse.member6_Y_pontoon_upper3.axial_stiffener_spacing	rad
floatingse.member6_Y_pontoon_upper3.ballast_grid
floatingse.member6_Y_pontoon_upper3.ballast_density	kg/m**3
floatingse.member6_Y_pontoon_upper3.ballast_volume	m**3
floatingse.member6_Y_pontoon_upper3.ballast_unit_cost	USD/kg
floatingse.member6_Y_pontoon_upper3:mass_user	kg
floatingse.member7_Y_pontoon_lower1.gc.d	m
floatingse.member7_Y_pontoon_lower1.gc.t	m
floatingse.member7_Y_pontoon_lower1.s
floatingse.member7_Y_pontoon_lower1.height	m
floatingse.member7_Y_pontoon_lower1.outer_diameter	m
floatingse.member7_Y_pontoon_lower1.ca_usr_grid
floatingse.member7_Y_pontoon_lower1.cd_usr_grid
floatingse.member7_Y_pontoon_lower1.wall_thickness	m
floatingse.member7_Y_pontoon_lower1.E	Pa
floatingse.member7_Y_pontoon_lower1.G	Pa
floatingse.member7_Y_pontoon_lower1.sigma_y	Pa
floatingse.member7_Y_pontoon_lower1.rho	kg/m**3
floatingse.member7_Y_pontoon_lower1.unit_cost	USD/kg
floatingse.member7_Y_pontoon_lower1.outfitting_factor
floatingse.member7_Y_pontoon_lower1.nodes_xyz	m
floatingse.member7_Y_pontoon_lower1.s_full	m
floatingse.member7_Y_pontoon_lower1.z_full	m
floatingse.member7_Y_pontoon_lower1.outer_diameter_full	m
floatingse.member7_Y_pontoon_lower1.s_ghost1
floatingse.member7_Y_pontoon_lower1.s_ghost2
floatingse.member7_Y_pontoon_lower1.s_in
floatingse.member7_Y_pontoon_lower1.s_const1
floatingse.member7_Y_pontoon_lower1.s_const2
floatingse.member7_Y_pontoon_lower1.layer_thickness	m
floatingse.member7_Y_pontoon_lower1.outer_diameter_in	m
floatingse.member7_Y_pontoon_lower1.E_user	Pa
floatingse.member7_Y_pontoon_lower1.outfitting_factor_in
floatingse.member7_Y_pontoon_lower1.layer_materials	n/a
floatingse.member7_Y_pontoon_lower1.ballast_materials	n/a
floatingse.member7_Y_pontoon_lower1.t_full	m
floatingse.member7_Y_pontoon_lower1.E_full	Pa
floatingse.member7_Y_pontoon_lower1.G_full	Pa
floatingse.member7_Y_pontoon_lower1.rho_full	kg/m**3
floatingse.member7_Y_pontoon_lower1.sigma_y_full	Pa
floatingse.member7_Y_pontoon_lower1.unit_cost_full	USD/kg
floatingse.member7_Y_pontoon_lower1.outfitting_full
floatingse.member7_Y_pontoon_lower1.grid_axial_joints
floatingse.member7_Y_pontoon_lower1.bulkhead_grid
floatingse.member7_Y_pontoon_lower1.bulkhead_thickness	m
floatingse.member7_Y_pontoon_lower1.ring_stiffener_web_height	m
floatingse.member7_Y_pontoon_lower1.ring_stiffener_web_thickness	m
floatingse.member7_Y_pontoon_lower1.ring_stiffener_flange_width	m
floatingse.member7_Y_pontoon_lower1.ring_stiffener_flange_thickness	m
floatingse.member7_Y_pontoon_lower1.ring_stiffener_spacing
floatingse.member7_Y_pontoon_lower1.axial_stiffener_web_height	m
floatingse.member7_Y_pontoon_lower1.axial_stiffener_web_thickness	m
floatingse.member7_Y_pontoon_lower1.axial_stiffener_flange_width	m
floatingse.member7_Y_pontoon_lower1.axial_stiffener_flange_thickness	m
floatingse.member7_Y_pontoon_lower1.axial_stiffener_spacing	rad
floatingse.member7_Y_pontoon_lower1.ballast_grid
floatingse.member7_Y_pontoon_lower1.ballast_density	kg/m**3
floatingse.member7_Y_pontoon_lower1.ballast_volume	m**3
floatingse.member7_Y_pontoon_lower1.ballast_unit_cost	USD/kg
floatingse.member7_Y_pontoon_lower1:mass_user	kg
floatingse.member8_Y_pontoon_lower2.gc.d	m
floatingse.member8_Y_pontoon_lower2.gc.t	m
floatingse.member8_Y_pontoon_lower2.s
floatingse.member8_Y_pontoon_lower2.height	m
floatingse.member8_Y_pontoon_lower2.outer_diameter	m
floatingse.member8_Y_pontoon_lower2.ca_usr_grid
floatingse.member8_Y_pontoon_lower2.cd_usr_grid
floatingse.member8_Y_pontoon_lower2.wall_thickness	m
floatingse.member8_Y_pontoon_lower2.E	Pa
floatingse.member8_Y_pontoon_lower2.G	Pa
floatingse.member8_Y_pontoon_lower2.sigma_y	Pa
floatingse.member8_Y_pontoon_lower2.rho	kg/m**3
floatingse.member8_Y_pontoon_lower2.unit_cost	USD/kg
floatingse.member8_Y_pontoon_lower2.outfitting_factor
floatingse.member8_Y_pontoon_lower2.nodes_xyz	m
floatingse.member8_Y_pontoon_lower2.s_full	m
floatingse.member8_Y_pontoon_lower2.z_full	m
floatingse.member8_Y_pontoon_lower2.outer_diameter_full	m
floatingse.member8_Y_pontoon_lower2.s_ghost1
floatingse.member8_Y_pontoon_lower2.s_ghost2
floatingse.member8_Y_pontoon_lower2.s_in
floatingse.member8_Y_pontoon_lower2.s_const1
floatingse.member8_Y_pontoon_lower2.s_const2
floatingse.member8_Y_pontoon_lower2.layer_thickness	m
floatingse.member8_Y_pontoon_lower2.outer_diameter_in	m
floatingse.member8_Y_pontoon_lower2.E_user	Pa
floatingse.member8_Y_pontoon_lower2.outfitting_factor_in
floatingse.member8_Y_pontoon_lower2.layer_materials	n/a
floatingse.member8_Y_pontoon_lower2.ballast_materials	n/a
floatingse.member8_Y_pontoon_lower2.t_full	m
floatingse.member8_Y_pontoon_lower2.E_full	Pa
floatingse.member8_Y_pontoon_lower2.G_full	Pa
floatingse.member8_Y_pontoon_lower2.rho_full	kg/m**3
floatingse.member8_Y_pontoon_lower2.sigma_y_full	Pa
floatingse.member8_Y_pontoon_lower2.unit_cost_full	USD/kg
floatingse.member8_Y_pontoon_lower2.outfitting_full
floatingse.member8_Y_pontoon_lower2.grid_axial_joints
floatingse.member8_Y_pontoon_lower2.bulkhead_grid
floatingse.member8_Y_pontoon_lower2.bulkhead_thickness	m
floatingse.member8_Y_pontoon_lower2.ring_stiffener_web_height	m
floatingse.member8_Y_pontoon_lower2.ring_stiffener_web_thickness	m
floatingse.member8_Y_pontoon_lower2.ring_stiffener_flange_width	m
floatingse.member8_Y_pontoon_lower2.ring_stiffener_flange_thickness	m
floatingse.member8_Y_pontoon_lower2.ring_stiffener_spacing
floatingse.member8_Y_pontoon_lower2.axial_stiffener_web_height	m
floatingse.member8_Y_pontoon_lower2.axial_stiffener_web_thickness	m
floatingse.member8_Y_pontoon_lower2.axial_stiffener_flange_width	m
floatingse.member8_Y_pontoon_lower2.axial_stiffener_flange_thickness	m
floatingse.member8_Y_pontoon_lower2.axial_stiffener_spacing	rad
floatingse.member8_Y_pontoon_lower2.ballast_grid
floatingse.member8_Y_pontoon_lower2.ballast_density	kg/m**3
floatingse.member8_Y_pontoon_lower2.ballast_volume	m**3
floatingse.member8_Y_pontoon_lower2.ballast_unit_cost	USD/kg
floatingse.member8_Y_pontoon_lower2:mass_user	kg
floatingse.member9_Y_pontoon_lower3.gc.d	m
floatingse.member9_Y_pontoon_lower3.gc.t	m
floatingse.member9_Y_pontoon_lower3.s
floatingse.member9_Y_pontoon_lower3.height	m
floatingse.member9_Y_pontoon_lower3.outer_diameter	m
floatingse.member9_Y_pontoon_lower3.ca_usr_grid
floatingse.member9_Y_pontoon_lower3.cd_usr_grid
floatingse.member9_Y_pontoon_lower3.wall_thickness	m
floatingse.member9_Y_pontoon_lower3.E	Pa
floatingse.member9_Y_pontoon_lower3.G	Pa
floatingse.member9_Y_pontoon_lower3.sigma_y	Pa
floatingse.member9_Y_pontoon_lower3.rho	kg/m**3
floatingse.member9_Y_pontoon_lower3.unit_cost	USD/kg
floatingse.member9_Y_pontoon_lower3.outfitting_factor
floatingse.member9_Y_pontoon_lower3.nodes_xyz	m
floatingse.member9_Y_pontoon_lower3.s_full	m
floatingse.member9_Y_pontoon_lower3.z_full	m
floatingse.member9_Y_pontoon_lower3.outer_diameter_full	m
floatingse.member9_Y_pontoon_lower3.s_ghost1
floatingse.member9_Y_pontoon_lower3.s_ghost2
floatingse.member9_Y_pontoon_lower3.s_in
floatingse.member9_Y_pontoon_lower3.s_const1
floatingse.member9_Y_pontoon_lower3.s_const2
floatingse.member9_Y_pontoon_lower3.layer_thickness	m
floatingse.member9_Y_pontoon_lower3.outer_diameter_in	m
floatingse.member9_Y_pontoon_lower3.E_user	Pa
floatingse.member9_Y_pontoon_lower3.outfitting_factor_in
floatingse.member9_Y_pontoon_lower3.layer_materials	n/a
floatingse.member9_Y_pontoon_lower3.ballast_materials	n/a
floatingse.member9_Y_pontoon_lower3.t_full	m
floatingse.member9_Y_pontoon_lower3.E_full	Pa
floatingse.member9_Y_pontoon_lower3.G_full	Pa
floatingse.member9_Y_pontoon_lower3.rho_full	kg/m**3
floatingse.member9_Y_pontoon_lower3.sigma_y_full	Pa
floatingse.member9_Y_pontoon_lower3.unit_cost_full	USD/kg
floatingse.member9_Y_pontoon_lower3.outfitting_full
floatingse.member9_Y_pontoon_lower3.grid_axial_joints
floatingse.member9_Y_pontoon_lower3.bulkhead_grid
floatingse.member9_Y_pontoon_lower3.bulkhead_thickness	m
floatingse.member9_Y_pontoon_lower3.ring_stiffener_web_height	m
floatingse.member9_Y_pontoon_lower3.ring_stiffener_web_thickness	m
floatingse.member9_Y_pontoon_lower3.ring_stiffener_flange_width	m
floatingse.member9_Y_pontoon_lower3.ring_stiffener_flange_thickness	m
floatingse.member9_Y_pontoon_lower3.ring_stiffener_spacing
floatingse.member9_Y_pontoon_lower3.axial_stiffener_web_height	m
floatingse.member9_Y_pontoon_lower3.axial_stiffener_web_thickness	m
floatingse.member9_Y_pontoon_lower3.axial_stiffener_flange_width	m
floatingse.member9_Y_pontoon_lower3.axial_stiffener_flange_thickness	m
floatingse.member9_Y_pontoon_lower3.axial_stiffener_spacing	rad
floatingse.member9_Y_pontoon_lower3.ballast_grid
floatingse.member9_Y_pontoon_lower3.ballast_density	kg/m**3
floatingse.member9_Y_pontoon_lower3.ballast_volume	m**3
floatingse.member9_Y_pontoon_lower3.ballast_unit_cost	USD/kg
floatingse.member9_Y_pontoon_lower3:mass_user	kg
floatingse.line_length	m
floatingse.line_diameter	m
floatingse.anchor_radius	m
floatingse.anchor_mass	kg
floatingse.anchor_cost	USD
floatingse.anchor_max_vertical_load	N
floatingse.anchor_max_lateral_load	N
floatingse.line_mass_density_coeff	kg/m**3
floatingse.line_stiffness_coeff	N/m**2
floatingse.line_breaking_load_coeff	N/m**2
floatingse.line_cost_rate_coeff	USD/m**3
floatingse.max_surge_fraction
floatingse.operational_heel	rad
floating.location	m
floating.member0_main_column:s
floating.member0_main_column:outer_diameter	m
floating.member0_main_column:grid_axial_joints
floating.member1_column1:s
floating.member1_column1:outer_diameter	m
floating.member1_column1:grid_axial_joints
floating.member2_column2:s
floating.member2_column2:outer_diameter	m
floating.member2_column2:grid_axial_joints
floating.member3_column3:s
floating.member3_column3:outer_diameter	m
floating.member3_column3:grid_axial_joints
floating.member4_Y_pontoon_upper1:s
floating.member4_Y_pontoon_upper1:outer_diameter	m
floating.member4_Y_pontoon_upper1:grid_axial_joints
floating.member5_Y_pontoon_upper2:s
floating.member5_Y_pontoon_upper2:outer_diameter	m
floating.member5_Y_pontoon_upper2:grid_axial_joints
floating.member6_Y_pontoon_upper3:s
floating.member6_Y_pontoon_upper3:outer_diameter	m
floating.member6_Y_pontoon_upper3:grid_axial_joints
floating.member7_Y_pontoon_lower1:s
floating.member7_Y_pontoon_lower1:outer_diameter	m
floating.member7_Y_pontoon_lower1:grid_axial_joints
floating.member8_Y_pontoon_lower2:s
floating.member8_Y_pontoon_lower2:outer_diameter	m
floating.member8_Y_pontoon_lower2:grid_axial_joints
floating.member9_Y_pontoon_lower3:s
floating.member9_Y_pontoon_lower3:outer_diameter	m
floating.member9_Y_pontoon_lower3:grid_axial_joints
floating.memgrid0.s_in
floating.memgrid0.s_grid
floating.memgrid0.outer_diameter_in	m
floating.memgrid0.ca_usr_geom
floating.memgrid0.cd_usr_geom
floating.memgrid0.layer_thickness_in	m
floating.memgrid1.s_in
floating.memgrid1.s_grid
floating.memgrid1.outer_diameter_in	m
floating.memgrid1.ca_usr_geom
floating.memgrid1.cd_usr_geom
floating.memgrid1.layer_thickness_in	m
floating.memgrid2.s_in
floating.memgrid2.s_grid
floating.memgrid2.outer_diameter_in	m
floating.memgrid2.ca_usr_geom
floating.memgrid2.cd_usr_geom
floating.memgrid2.layer_thickness_in	m
floating.memgrid3.s_in
floating.memgrid3.s_grid
floating.memgrid3.outer_diameter_in	m
floating.memgrid3.ca_usr_geom
floating.memgrid3.cd_usr_geom
floating.memgrid3.layer_thickness_in	m
floating.memgrid4.s_in
floating.memgrid4.s_grid
floating.memgrid4.outer_diameter_in	m
floating.memgrid4.ca_usr_geom
floating.memgrid4.cd_usr_geom
floating.memgrid4.layer_thickness_in	m
floating.memgrid5.s_in
floating.memgrid5.s_grid
floating.memgrid5.outer_diameter_in	m
floating.memgrid5.ca_usr_geom
floating.memgrid5.cd_usr_geom
floating.memgrid5.layer_thickness_in	m
floating.memgrid6.s_in
floating.memgrid6.s_grid
floating.memgrid6.outer_diameter_in	m
floating.memgrid6.ca_usr_geom
floating.memgrid6.cd_usr_geom
floating.memgrid6.layer_thickness_in	m
floating.memgrid7.s_in
floating.memgrid7.s_grid
floating.memgrid7.outer_diameter_in	m
floating.memgrid7.ca_usr_geom
floating.memgrid7.cd_usr_geom
floating.memgrid7.layer_thickness_in	m
floating.memgrid8.s_in
floating.memgrid8.s_grid
floating.memgrid8.outer_diameter_in	m
floating.memgrid8.ca_usr_geom
floating.memgrid8.cd_usr_geom
floating.memgrid8.layer_thickness_in	m
floating.memgrid9.s_in
floating.memgrid9.s_grid
floating.memgrid9.outer_diameter_in	m
floating.memgrid9.ca_usr_geom
floating.memgrid9.cd_usr_geom
floating.memgrid9.layer_thickness_in	m
floating.location_in	m
mooring.nodes_location	m
mooring.joints_xyz	m
mooring.nodes_joint_name	n/a
mooring.unstretched_length_in	m
mooring.line_diameter_in	m
mooring.line_mass_density_coeff	kg/m**3
mooring.line_stiffness_coeff	N/m**2
mooring.line_breaking_load_coeff	N/m**2
mooring.line_cost_rate_coeff	USD/m**3
mooring.line_transverse_added_mass_coeff	kg/m**3
mooring.line_tangential_added_mass_coeff	kg/m**3
mooring.line_transverse_drag_coeff	N/m**2
mooring.line_tangential_drag_coeff	N/m**2

Add this for fanciness on the table :class: datatable