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Python Data.pax方法代码示例

本文整理汇总了Python中SUAVE.Core.Data.pax方法的典型用法代码示例。如果您正苦于以下问题:Python Data.pax方法的具体用法?Python Data.pax怎么用?Python Data.pax使用的例子?那么, 这里精选的方法代码示例或许可以为您提供帮助。您也可以进一步了解该方法所在SUAVE.Core.Data的用法示例。


在下文中一共展示了Data.pax方法的5个代码示例,这些例子默认根据受欢迎程度排序。您可以为喜欢或者感觉有用的代码点赞,您的评价将有助于系统推荐出更棒的Python代码示例。

示例1: payload

# 需要导入模块: from SUAVE.Core import Data [as 别名]
# 或者: from SUAVE.Core.Data import pax [as 别名]
def payload(TOW, empty, num_pax, wt_cargo, wt_passenger = 195*Units.lbs,wt_baggage = 30*Units.lbs):
    """ Calculate the weight of the payload and the resulting fuel mass
    
    Assumptions:
        based on FAA guidelines for weight of passengers
        
    Source: 
        N/A
        
    Inputs:
        TOW -                                                              [kilograms]
        wt_empty - Operating empty weight of the aircraft                  [kilograms]
        num_pax - number of passengers on the aircraft                     [dimensionless]
        wt_cargo - weight of cargo being carried on the aircraft           [kilogram]
        wt_passenger - weight of each passenger on the aircraft            [kilogram]
        wt_baggage - weight of the baggage for each passenger              [kilogram]
    
    Outputs:
        output - a data dictionary with fields:
            payload - weight of the passengers plus baggage and paid cargo [kilograms]
            pax - weight of all the passengers                             [kilogram]
            bag - weight of all the baggage                                [kilogram]
            fuel - weight of the fuel carried                              [kilogram]
            empty - operating empty weight of the aircraft                 [kilograms]
               
    Properties Used:
        N/A
    """ 
    
    # process
    wt_pax     = wt_passenger * num_pax
    wt_bag     = wt_baggage * num_pax 
    wt_payload = wt_pax + wt_bag + wt_cargo
    wt_fuel    = TOW - wt_payload - empty
    
    # packup outputs
    output = Data()
    output.payload = wt_payload
    output.pax     = wt_pax   
    output.bag     = wt_bag
    output.fuel    = wt_fuel
    output.empty   = empty
  
    return output
开发者ID:michK,项目名称:SUAVE,代码行数:46,代码来源:payload.py

示例2: main

# 需要导入模块: from SUAVE.Core import Data [as 别名]
# 或者: from SUAVE.Core.Data import pax [as 别名]
def main():
  
    vehicle = vehicle_setup()    
    weight = Tube_Wing.empty(vehicle)
    
    # regression values    
    actual = Data()
    actual.payload         = 27349.9081525 #includes cargo #17349.9081525 #without cargo
    actual.pax             = 15036.587065500002
    actual.bag             = 2313.3210870000003
    actual.fuel            = 12977.803363592691 #includes cargo #22177.6377131 #without cargo
    actual.empty           = 38688.08848390731
    actual.wing            = 6649.709658738429
    actual.fuselage        = 6642.061164271899
    actual.propulsion      = 6838.185174956626
    actual.landing_gear    = 3160.632
    actual.systems         = 13479.10479056802
    actual.wt_furnish      = 6431.80372889
    actual.horizontal_tail = 1037.7414196819743
    actual.vertical_tail   = 629.0387683502595
    actual.rudder          = 251.61550734010382
    
    # error calculations
    error                 = Data()
    error.payload         = (actual.payload - weight.payload)/actual.payload
    error.pax             = (actual.pax - weight.pax)/actual.pax
    error.bag             = (actual.bag - weight.bag)/actual.bag
    error.fuel            = (actual.fuel - weight.fuel)/actual.fuel
    error.empty           = (actual.empty - weight.empty)/actual.empty
    error.wing            = (actual.wing - weight.wing)/actual.wing
    error.fuselage        = (actual.fuselage - weight.fuselage)/actual.fuselage
    error.propulsion      = (actual.propulsion - weight.propulsion)/actual.propulsion
    error.landing_gear    = (actual.landing_gear - weight.landing_gear)/actual.landing_gear
    error.systems         = (actual.systems - weight.systems)/actual.systems
    error.wt_furnish      = (actual.wt_furnish - weight.systems_breakdown.furnish)/actual.wt_furnish
    error.horizontal_tail = (actual.horizontal_tail - weight.horizontal_tail)/actual.horizontal_tail
    error.vertical_tail   = (actual.vertical_tail - weight.vertical_tail)/actual.vertical_tail
    error.rudder          = (actual.rudder - weight.rudder)/actual.rudder
    
    print('Results (kg)')
    print(weight)
    
    print('Relative Errors')
    print(error)  
      
    for k,v in list(error.items()):
        assert(np.abs(v)<1E-6)    
   
    #General Aviation weights; note that values are taken from Raymer,
    #but there is a huge spread among the GA designs, so individual components
    #differ a good deal from the actual design
   
    vehicle        = vehicle_setup_general_aviation()
    GTOW           = vehicle.mass_properties.max_takeoff
    weight         = General_Aviation.empty(vehicle)
    weight.fuel    = vehicle.fuel.mass_properties.mass 
    actual         = Data()
    actual.bag     = 0.
    actual.empty   = 618.485310343
    actual.fuel    = 144.69596603

    actual.wing            = 124.673093906
    actual.fuselage        = 119.522072873
    actual.propulsion      = 194.477769922 #includes power plant and propeller, does not include fuel system
    actual.landing_gear    = 44.8033840543+5.27975390045
    actual.furnishing      = 37.8341395817
    actual.electrical      = 36.7532226254
    actual.control_systems = 14.8331955546
    actual.fuel_systems    = 15.6859717453
    actual.systems         = 108.096549345

    error                 = Data()
    error.fuel            = (actual.fuel - weight.fuel)/actual.fuel
    error.empty           = (actual.empty - weight.empty)/actual.empty
    error.wing            = (actual.wing - weight.wing)/actual.wing
    error.fuselage        = (actual.fuselage - weight.fuselage)/actual.fuselage
    error.propulsion      = (actual.propulsion - weight.propulsion)/actual.propulsion
    error.landing_gear    = (actual.landing_gear - (weight.landing_gear_main+weight.landing_gear_nose))/actual.landing_gear
    error.furnishing      = (actual.furnishing-weight.systems_breakdown.furnish)/actual.furnishing
    error.electrical      = (actual.electrical-weight.systems_breakdown.electrical)/actual.electrical
    error.control_systems = (actual.control_systems-weight.systems_breakdown.control_systems)/actual.control_systems
    error.fuel_systems    = (actual.fuel_systems-weight.systems_breakdown.fuel_system)/actual.fuel_systems
    error.systems         = (actual.systems - weight.systems)/actual.systems

    print('actual.systems=', actual.systems)
    print('General Aviation Results (kg)')
    print(weight)

    print('Relative Errors')
    print(error)  

    for k,v in list(error.items()):
        assert(np.abs(v)<1e-6)    

    # BWB WEIGHTS
    vehicle = bwb_setup()    
    weight  = BWB.empty(vehicle)
            
    # regression values    
    actual = Data()
#.........这里部分代码省略.........
开发者ID:suavecode,项目名称:SUAVE,代码行数:103,代码来源:weights.py

示例3: main

# 需要导入模块: from SUAVE.Core import Data [as 别名]
# 或者: from SUAVE.Core.Data import pax [as 别名]
def main():
  
    vehicle = vehicle_setup()    
    weight = Tube_Wing.empty(vehicle)
    
    # regression values    
    actual = Data()
    actual.payload         = 27349.9081525 #includes cargo #17349.9081525 #without cargo
    actual.pax             = 15036.587065500002
    actual.bag             = 2313.3210870000003
    actual.fuel            = 12990.957450008464 #includes cargo #22177.6377131 #without cargo
    actual.empty           = 38674.934397491539
    actual.wing            = 6649.7096587384294
    actual.fuselage        = 6642.0611642718986
    actual.propulsion      = 6838.1851749566231
    actual.landing_gear    = 3160.632
    actual.systems         = 13479.10479056802
    actual.wt_furnish      = 6431.80372889
    actual.horizontal_tail = 1024.5873332662029
    actual.vertical_tail   = 629.03876835025949
    actual.rudder          = 251.61550734010382
    
    # error calculations
    error                 = Data()
    error.payload         = (actual.payload - weight.payload)/actual.payload
    error.pax             = (actual.pax - weight.pax)/actual.pax
    error.bag             = (actual.bag - weight.bag)/actual.bag
    error.fuel            = (actual.fuel - weight.fuel)/actual.fuel
    error.empty           = (actual.empty - weight.empty)/actual.empty
    error.wing            = (actual.wing - weight.wing)/actual.wing
    error.fuselage        = (actual.fuselage - weight.fuselage)/actual.fuselage
    error.propulsion      = (actual.propulsion - weight.propulsion)/actual.propulsion
    error.landing_gear    = (actual.landing_gear - weight.landing_gear)/actual.landing_gear
    error.systems         = (actual.systems - weight.systems)/actual.systems
    error.wt_furnish      = (actual.wt_furnish - weight.systems_breakdown.furnish)/actual.wt_furnish
    error.horizontal_tail = (actual.horizontal_tail - weight.horizontal_tail)/actual.horizontal_tail
    error.vertical_tail   = (actual.vertical_tail - weight.vertical_tail)/actual.vertical_tail
    error.rudder          = (actual.rudder - weight.rudder)/actual.rudder
    
    print 'Results (kg)'
    print weight
    
    print 'Relative Errors'
    print error  
      
    for k,v in error.items():
        assert(np.abs(v)<1E-6)    
   
    #General Aviation weights; note that values are taken from Raymer,
    #but there is a huge spread among the GA designs, so individual components
    #differ a good deal from the actual design
   
    vehicle        = vehicle_setup_general_aviation()
    GTOW           = vehicle.mass_properties.max_takeoff
    weight         = General_Aviation.empty(vehicle)
    weight.fuel    = vehicle.fuel.mass_properties.mass 
    actual         = Data()
    actual.bag     = 0.
    actual.empty   = 618.485310343
    actual.fuel    = 144.69596603

    actual.wing            = 124.673093906
    actual.fuselage        = 119.522072873
    actual.propulsion      = 194.477769922 #includes power plant and propeller, does not include fuel system
    actual.landing_gear    = 44.8033840543+5.27975390045
    actual.furnishing      = 37.8341395817
    actual.electrical      = 36.7532226254
    actual.control_systems = 14.8331955546
    actual.fuel_systems    = 15.6859717453
    actual.systems         = 108.096549345

    error                 = Data()
    error.fuel            = (actual.fuel - weight.fuel)/actual.fuel
    error.empty           = (actual.empty - weight.empty)/actual.empty
    error.wing            = (actual.wing - weight.wing)/actual.wing
    error.fuselage        = (actual.fuselage - weight.fuselage)/actual.fuselage
    error.propulsion      = (actual.propulsion - weight.propulsion)/actual.propulsion
    error.landing_gear    = (actual.landing_gear - (weight.landing_gear_main+weight.landing_gear_nose))/actual.landing_gear
    error.furnishing      = (actual.furnishing-weight.systems_breakdown.furnish)/actual.furnishing
    error.electrical      = (actual.electrical-weight.systems_breakdown.electrical)/actual.electrical
    error.control_systems = (actual.control_systems-weight.systems_breakdown.control_systems)/actual.control_systems
    error.fuel_systems    = (actual.fuel_systems-weight.systems_breakdown.fuel_system)/actual.fuel_systems
    error.systems         = (actual.systems - weight.systems)/actual.systems

    print 'actual.systems=', actual.systems
    print 'General Aviation Results (kg)'
    print weight

    print 'Relative Errors'
    print error  

    for k,v in error.items():
        assert(np.abs(v)<1e-6)    
   
    return
开发者ID:michK,项目名称:SUAVE,代码行数:97,代码来源:weights.py

示例4: main

# 需要导入模块: from SUAVE.Core import Data [as 别名]
# 或者: from SUAVE.Core.Data import pax [as 别名]

#.........这里部分代码省略.........
    vehicle.append_component(turbofan)      
    

    vehicle.passengers                                  = 170.                            # Number of passengers
    vehicle.mass_properties.cargo                       = 0.  * Units.kilogram            # Mass of cargo
    vehicle.systems.control                             = "fully powered"                 # Specify fully powered, partially powered or anything else is fully aerodynamic
    vehicle.systems.accessories                         = "medium-range"                  # Specify what type of aircraft you have
    
    vehicle.reference_area                              = 124.862  * Units.meter**2  # Wing gross area in square meters
    wing = SUAVE.Components.Wings.Wing()
    wing.tag = 'main_wing'
    wing.spans.projected          = 50.      * Units.meter     # Span in meters
    wing.taper                    = 0.2                        # Taper ratio
    wing.thickness_to_chord       = 0.08                       # Thickness-to-chord ratio
    wing.sweep                    = .4363323 * Units.rad       # sweep angle in degrees
    wing.chords.root              = 15.      * Units.meter     # Wing root chord length
    wing.chords.mean_aerodynamic  = 10.      * Units.meters    # Length of the mean aerodynamic chord of the wing
    wing.origin                 = [20,0,0] * Units.meters    # Location of main wing from origin of the vehicle
    wing.aerodynamic_center       = [3,0,0]  * Units.meters    # Location of aerodynamic center from origin of the main wing
    vehicle.append_component(wing)
    
    fuselage = SUAVE.Components.Fuselages.Fuselage()
    fuselage.tag = 'fuselage'    
    fuselage.areas.wetted             = 688.64    * Units.meter**2  # Fuselage wetted area 
    fuselage.differential_pressure    = 55960.5   * Units.pascal    # Maximum differential pressure
    fuselage.width                    = 4.        * Units.meter     # Width of the fuselage
    fuselage.heights.maximum          = 4.        * Units.meter     # Height of the fuselage
    fuselage.lengths.total            = 58.4      * Units.meter     # Length of the fuselage
    fuselage.number_coach_seats       = 200.       
    vehicle.append_component(fuselage)
    
    wing = SUAVE.Components.Wings.Wing()
    wing.tag = 'horizontal_stabilizer'    
    wing.areas.reference          = 75.     * Units.meters**2 # Area of the horizontal tail
    wing.spans.projected          = 15.     * Units.meters    # Span of the horizontal tail
    wing.sweep                    = 38.     * Units.deg       # Sweep of the horizontal tail
    wing.chords.mean_aerodynamic  = 5.      * Units.meters    # Length of the mean aerodynamic chord of the horizontal tail
    wing.thickness_to_chord       = 0.07                      # Thickness-to-chord ratio of the horizontal tail
    wing.areas.exposed            = 199.7792                  # Exposed area of the horizontal tail
    wing.areas.wetted             = 249.724                   # Wetted area of the horizontal tail
    wing.origin                 = [45,0,0]                  # Location of horizontal tail from origin of the vehicle
    wing.aerodynamic_center       = [3,0,0]                   # Location of aerodynamic center from origin of the horizontal tail
    vehicle.append_component(wing)    
    
    wing = SUAVE.Components.Wings.Wing()
    wing.tag = 'vertical_stabilizer'    
    wing.areas.reference     = 60.     * Units.meters**2 # Area of the vertical tail
    wing.spans.projected     = 15.     * Units.meters    # Span of the vertical tail
    wing.thickness_to_chord  = 0.07                      # Thickness-to-chord ratio of the vertical tail
    wing.sweep               = 40.     * Units.deg       # Sweep of the vertical tail
    wing.t_tail              = "false"                   # Set to "yes" for a T-tail
    vehicle.append_component(wing)   
    
    weight = Tube_Wing.empty(vehicle)
    
    
    actual = Data()
    actual.payload = 17349.9081525
    actual.pax = 15036.5870655
    actual.bag = 2313.321087
    actual.fuel = -13680.6265874
    actual.empty = 75346.5184349
    actual.wing = 27694.192985
    actual.fuselage = 11423.9380852
    actual.propulsion = 6855.68572746 
    actual.landing_gear = 3160.632
    actual.systems = 16655.7076511
    actual.wt_furnish = 7466.1304102
    actual.horizontal_tail = 2191.30720639
    actual.vertical_tail = 5260.75341411
    actual.rudder = 2104.30136565    
    
    error = Data()
    error.payload = (actual.payload - weight.payload)/actual.payload
    error.pax = (actual.pax - weight.pax)/actual.pax
    error.bag = (actual.bag - weight.bag)/actual.bag
    error.fuel = (actual.fuel - weight.fuel)/actual.fuel
    error.empty = (actual.empty - weight.empty)/actual.empty
    error.wing = (actual.wing - weight.wing)/actual.wing
    error.fuselage = (actual.fuselage - weight.fuselage)/actual.fuselage
    error.propulsion = (actual.propulsion - weight.propulsion)/actual.propulsion
    error.landing_gear = (actual.landing_gear - weight.landing_gear)/actual.landing_gear
    error.systems = (actual.systems - weight.systems)/actual.systems
    error.wt_furnish = (actual.wt_furnish - weight.systems_breakdown.furnish)/actual.wt_furnish
    
    error.horizontal_tail = (actual.horizontal_tail - weight.horizontal_tail)/actual.horizontal_tail
    error.vertical_tail = (actual.vertical_tail - weight.vertical_tail)/actual.vertical_tail
    error.rudder = (actual.rudder - weight.rudder)/actual.rudder
    
    print 'Results (kg)'
    print weight
    
    print 'Relative Errors'
    print error  
      
    for k,v in error.items():
        assert(np.abs(v)<0.001)    
   
    
    return
开发者ID:Alexandrovich,项目名称:SUAVE,代码行数:104,代码来源:weights.py

示例5: main

# 需要导入模块: from SUAVE.Core import Data [as 别名]
# 或者: from SUAVE.Core.Data import pax [as 别名]
def main():
    vehicle = SUAVE.Vehicle()# Create the vehicle for testing
    
    # Parameters Required
    vehicle.envelope.ultimate_load                      = 3.5                             # Ultimate load
    vehicle.mass_properties.max_takeoff                 = 79015.8 * Units.kilograms       # Maximum takeoff weight in kilograms
    vehicle.mass_properties.max_zero_fuel               = 79015.8 * 0.9 * Units.kilograms # Maximum zero fuel weight in kilograms
    vehicle.envelope.limit_load                         = 1.5                             # Limit Load
    
    turbofan = SUAVE.Components.Propulsors.TurboFanPASS()
    turbofan.tag = 'turbo_fan'    
    turbofan.number_of_engines   = 2.                              # Number of engines on the aircraft
    turbofan.design_thrust  = 200.   * Units.newton    # Define Thrust in Newtons    
    vehicle.append_component(turbofan) 

    vehicle.passengers                                  = 170.                            # Number of passengers
    vehicle.mass_properties.cargo                       = 0.  * Units.kilogram            # Mass of cargo
    vehicle.systems.control                             = "fully powered"                 # Specify fully powered, partially powered or anything else is fully aerodynamic
    vehicle.systems.accessories                         = "medium-range"                  # Specify what type of aircraft you have
    
    vehicle.reference_area                              = 124.862  * Units.meter**2  # Wing gross area in square meters
    wing = SUAVE.Components.Wings.Wing()
    wing.tag = 'main_wing'
    wing.spans.projected          = 50.      * Units.meter     # Span in meters
    wing.taper                    = 0.2                        # Taper ratio
    wing.thickness_to_chord       = 0.08                       # Thickness-to-chord ratio
    wing.sweep                    = .4363323 * Units.rad       # sweep angle in degrees
    wing.chords.root              = 15.      * Units.meter     # Wing root chord length
    wing.chords.mean_aerodynamic  = 10.      * Units.meters    # Length of the mean aerodynamic chord of the wing
    wing.origin                 = [20,0,0] * Units.meters    # Location of main wing from origin of the vehicle
    wing.aerodynamic_center       = [3,0,0]  * Units.meters    # Location of aerodynamic center from origin of the main wing
    vehicle.append_component(wing)
    
    fuselage = SUAVE.Components.Fuselages.Fuselage()
    fuselage.tag = 'fuselage'    
    fuselage.areas.wetted             = 688.64    * Units.meter**2  # Fuselage wetted area 
    fuselage.differential_pressure    = 55960.5   * Units.pascal    # Maximum differential pressure
    fuselage.width                    = 4.        * Units.meter     # Width of the fuselage
    fuselage.heights.maximum          = 4.        * Units.meter     # Height of the fuselage
    fuselage.lengths.total            = 58.4      * Units.meter     # Length of the fuselage
    fuselage.number_coach_seats       = 200.       
    vehicle.append_component(fuselage)
    
    wing = SUAVE.Components.Wings.Wing()
    wing.tag = 'horizontal_stabilizer'    
    wing.areas.reference          = 75.     * Units.meters**2 # Area of the horizontal tail
    wing.spans.projected          = 15.     * Units.meters    # Span of the horizontal tail
    wing.sweep                    = 38.     * Units.deg       # Sweep of the horizontal tail
    wing.chords.mean_aerodynamic  = 5.      * Units.meters    # Length of the mean aerodynamic chord of the horizontal tail
    wing.thickness_to_chord       = 0.07                      # Thickness-to-chord ratio of the horizontal tail
    wing.areas.exposed            = 199.7792                  # Exposed area of the horizontal tail
    wing.areas.wetted             = 249.724                   # Wetted area of the horizontal tail
    wing.origin                 = [45,0,0]                  # Location of horizontal tail from origin of the vehicle
    wing.aerodynamic_center       = [3,0,0]                   # Location of aerodynamic center from origin of the horizontal tail
    vehicle.append_component(wing)    
    
    wing = SUAVE.Components.Wings.Wing()
    wing.tag = 'vertical_stabilizer'    
    wing.areas.reference     = 60.     * Units.meters**2 # Area of the vertical tail
    wing.spans.projected     = 15.     * Units.meters    # Span of the vertical tail
    wing.thickness_to_chord  = 0.07                      # Thickness-to-chord ratio of the vertical tail
    wing.sweep               = 40.     * Units.deg       # Sweep of the vertical tail
    wing.t_tail              = "false"                   # Set to "yes" for a T-tail
    vehicle.append_component(wing)   
    
    weight = Tube_Wing.empty(vehicle)
    
    actual = Data()
    actual.payload = 17349.9081525
    actual.pax = 15036.5870655
    actual.bag = 2313.321087
    actual.fuel = -6993.89102491
    actual.empty = 68659.7828724
    actual.wing = 27694.192985
    actual.fuselage = 11504.5186408
    actual.propulsion = 88.3696093424
    actual.landing_gear = 3160.632
    actual.systems = 16655.7076511
    actual.wt_furnish = 7466.1304102
    actual.horizontal_tail = 2191.30720639
    actual.vertical_tail = 5260.75341411
    actual.rudder = 2104.30136565    
    
    error = Data()
    error.payload = (actual.payload - weight.payload)/actual.payload
    error.pax = (actual.pax - weight.pax)/actual.pax
    error.bag = (actual.bag - weight.bag)/actual.bag
    error.fuel = (actual.fuel - weight.fuel)/actual.fuel
    error.empty = (actual.empty - weight.empty)/actual.empty
    error.wing = (actual.wing - weight.wing)/actual.wing
    error.fuselage = (actual.fuselage - weight.fuselage)/actual.fuselage
    error.propulsion = (actual.propulsion - weight.propulsion)/actual.propulsion
    error.landing_gear = (actual.landing_gear - weight.landing_gear)/actual.landing_gear
    error.systems = (actual.systems - weight.systems)/actual.systems
    error.wt_furnish = (actual.wt_furnish - weight.wt_furnish)/actual.wt_furnish
    error.horizontal_tail = (actual.horizontal_tail - weight.horizontal_tail)/actual.horizontal_tail
    error.vertical_tail = (actual.vertical_tail - weight.vertical_tail)/actual.vertical_tail
    error.rudder = (actual.rudder - weight.rudder)/actual.rudder
      
    for k,v in error.items():
#.........这里部分代码省略.........
开发者ID:aerialhedgehog,项目名称:SUAVE,代码行数:103,代码来源:test_weights.py


注:本文中的SUAVE.Core.Data.pax方法示例由纯净天空整理自Github/MSDocs等开源代码及文档管理平台,相关代码片段筛选自各路编程大神贡献的开源项目,源码版权归原作者所有,传播和使用请参考对应项目的License;未经允许,请勿转载。