A Preliminary Design Analysis for an Uninhabited Long Range Supersonic Strike Vehicle
Instructors: Neil Weston and Carl Johnson
By Michael Lopez
December 5, 2014
I certify that I have abided by the honor code of the Georgia Institute of Technology and followed the collaboration guidelines as specified in the project description for this assignment
Abstract
This document is a preliminary design for the creation of an uninhabited long range strike
vehicle. The design process used for the creation of this vehicle was primarily taken from Dr.
Jan Roskam’s series of aircraft design books. A figure of merits analysis was performed to
determine to best component configuration. Using these configuration choices, a weight
sizing analysis was performed based on the mission profile, mission fuel fractions, and the
class I drag polar to produce a takeoff weight for the vehicle. Subsequently, a constraint
analysis was performed on each segment of flight in order to produce an optimal thrust to
weight ratio at sea level takeoff and an optimal wing loading at takeoff. These ratios
produced preliminary values for thrust and wing area. Using all of this information, a
preliminary component design of the fuselage, wing, tail, high lift devices, and control
surfaces was performed. Finally, landing gear were attached to the aircraft and the entire
configuration was weighed and balanced to produce a finalized initial aircraft design. In
addition to this design process, trade studies were performed on key assumptions and design
decisions throughout the process to provide justification of various choices and demonstrate
the impact that changing these values would have on important design parameters.
Nomenclature
α = thrust lapse
β = vehicle weight over vehicle takeoff weight
Λ = quarter chord sweep angle
Γ = dihedral angle
λ = taper ratio
ρ = density
μ = turn bank angle
μto = ground friction coefficient
AR = main wing aspect ratio
b = wing span
c = chord
CD,o = coefficient of zero lift drag
CD = coefficient of drag
Cf = coefficient of skin friction
CL = coefficient of lift
d = diameter
e = Oswald’s efficiency factor
2
g0 = gravitational acceleration
h = altitude
KΛ = sweep coefficient
K1 = 1st order drag polar coefficient
K2 = 2nd order drag polar coefficient
kL = approach speed safety factor
kTO = takeoff speed safety factor
M = vehicle Mach number
n = load factor
q = dynamic pressure
R = vehicle range
RC = vehicle rate of climb
S = component area
SG = takeoff distance
Swet = vehicle wetted area
Tmax = maximum engine thrust
TSL = thrust at sea level
TSFC = thrust specific fuel consumption
t/c = thickness to chord ratio
T/W = thrust to weight ratio
v = vehicle speed
V = volumetric coefficient
WE = empty weight
WF = maximum fuel weight
WP = payload weight
WTO = maximum takeoff weight
W/S = wing loading
List of Figures
Figure 1: Final Vehicle Configuration..........................................................................................................................10
Figure 2: Vehicle Payload Location.............................................................................................................................11
Figure 3: Mission Profile..............................................................................................................................................12
Figure 4: Similar Vehicle Weight Regression..............................................................................................................13
Figure 5: Aspect Ratio Trade Study
Figure 6: Thickness to Chord Ratio Trade Study
3
Figure 7: Vehicle Accleration Trade Study
Figure 8: Thrust Specific Fuel Consumption Trade Study
Figure 9: Supercruise Mach Number Trade Study
Figure 10: Takeoff Assumption Comparison
Figure 11: Constraint Analysis
Figure 12: Descent Rate Trade Study
Figure 13: Load Factor Trade Study
Figure 14: Maximum Lift Coefficient on Approach Trade Study................................................................................33
Figure 15: Takeoff Distance Trade Study.....................................................................................................................34
Figure 16: Fuselage Top View......................................................................................................................................36
Figure 17: Fuselage Side View.....................................................................................................................................36
Figure 18: Fuselage Front View
Figure 19: Coefficient of Lift versus Angle of Attack for NACA 64-204
Figure 20: Coefficient of Drag versus Angle of Attack for NACA 64-204
Figure 21: Coefficient of Moment about the Leading Edge versus Angle of Attack for NACA 64-204.....................39
Figure 22: 2-D Drag Polar for NACA 64-204..............................................................................................................40
Figure 23: Main Wing Top View..................................................................................................................................43
Figure 24: Main Wing Side View.................................................................................................................................43
Figure 25: Main Wing Front View
Figure 26: Tail Top View
Figure 27: Tail Side View
Figure 28: Tail Front View...........................................................................................................................................47
Figure 29: Vehicle Top View.......................................................................................................................................48
Figure 30: Vehicle Subsonic Leading Edge..................................................................................................................49
Figure 31: Neutral Point Location................................................................................................................................50
Figure 32: Center of Gravity Range
Figure 33: Weight-C.G. Excursion Diagram
Figure 34: Landing Gear Side View
4
Figure 35: Final Design Top View
Figure 36: Final Design Side View
Figure 37: Final Design Front View
List of Tables
Table 1: Analysis of Alternatives...................................................................................................................................7
Table 2: Wing Layout Selection.....................................................................................................................................8
Table 3: Wing Attachment Selection..............................................................................................................................8
Table 4: Number of Fuselages Selection........................................................................................................................9
Table 5: Tail Type Selection...........................................................................................................................................9
Table 6: Tail Attachment Selection................................................................................................................................9
Table 7: Number of Engines Selection.........................................................................................................................10
Table 8: Weight Sizing Assumptions...........................................................................................................................13
Table 9a: Mission Fuel Fractions..................................................................................................................................14
Table 9b: Mission Fuel Fractions (cont.) 14
Table 10: Additional Fuel Fractions
Table 11: Weight Sizing Analysis Results
Table 12: Drag Polar Assumptions
Table 13: Lift to Drag Ratios
Table 14: Simple Takeoff Analysis Values
Table 15: Frictional Takeoff Analysis Values
Table 16: Climb Analysis Values.................................................................................................................................25
Table 17: Descent 1 Analysis Values...........................................................................................................................25
Table 18: Descent 2 Analysis Values...........................................................................................................................25
Table 19: Supercruise Analysis Values........................................................................................................................26
Table 20: Dash 1 Analysis Values................................................................................................................................26
Table 21: Dash 2 Analysis Values................................................................................................................................26
Table 22: Subcruise Analysis Values...........................................................................................................................26
Table 23: Zoom Analysis Values..................................................................................................................................27
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Table 24: Acceleration Analysis Values.......................................................................................................................27
Table 25: Delivery Analysis Values
Table 26: Approach Analysis Values
Table 27: Service Ceiling Analysis Values
Table 28: Fuselage Component Weight and Volume
Table 29: Main Wing Specifications
Table 30: Maximum Lift Coefficients
Table 31: Flap Sizing Values........................................................................................................................................42
Table 32: Volumetric Coefficient Method....................................................................................................................44
Table 33: Tail Sizing Values.........................................................................................................................................45
Table 34: Neutral Point Analysis Values
Table 35: Neutral Point Calculations
Table 36: Gross Weight Ratios
Table 37: Vehicle Component Weights
Table 38: Component Centers of Gravity
Table 39: Vehicle Centers of Gravity
Table 40: Gear Strut Load Values
6
I. Introduction
The purpose of this RFP is to detail one potential configuration and design of an uninhabited long range strike
vehicle. This vehicle would be designed with the capability of performing high altitude, sustained supersonic flight,
delivering a weapons payload, and returning back to land. This vehicle would be used by the military to perform
strike missions on targets in potentially hazardous areas, thus making the unmanned nature of this vehicle highly
desirable. In addition, a vehicle without a pilot is capable of performing more hazardous and dangerous maneuvers
without considering the safety and health of the pilot. The primary design influences for this vehicle come from the
Northrop Grumman B-2 Spirit bomber and the Lockheed Martin F-22 Raptor. Many of the decisions made in the
configuration selection and subsequent analysis of the vehicle were made based on these or similar aircraft.
II. Preliminary Configuration Selection
A. Analysis of Alternatives
For the configuration of this aircraft, many different design choices were possible. However, by using the F-22
Raptor and B-2 Spirit as base points, the choices for this unmanned supersonic bomber became somewhat simpler.
In order to analyze and select the best layout and component configuration, a figure of merits analysis for each
important component choice was performed. The table of these alternatives is shown below in Table 1. The eventual
choices for the aircraft configuration have been highlighted.
Table 1: Analysis of Alternatives
Components AlternativesWing Layout Flying wing Conventional Tandem wing
Wing Attachment Low Middle High BlendedFuselage Shape Blended Rounded Circular Square
Number of Fuselages 0 1 2 3Tail Type V-tail Conventional H-tail T-tail
Tail Attachment One boom Two booms On fuselageNumber of Engines 1 2
B. Figures of Merit Analysis
In order to obtain the best choice for each component, a figure of merit analysis was done to analyze the benefits
of each possibility. The analysis was done on using a scale of important from one to five with one being an
unimportant design point and five being a crucial design point. The weighting is assigned to each figure of merit
based on its relative importance to the overall configuration. These weightings are arbitrary but they are made with
consideration to the preliminary design process first and the subsequent design with lesser importance. The possible
7
choices for each component are then graded on another scale of one to five with one being inferior and five being
superior.
The first design choice in the configuration of this vehicle was the wing chosen. The figure of merit analysis for
the various wing layouts is shown below in Table 2.
Table 2: Wing Layout Selection
Wing Layout
FOM Weight Flying wing Conventional Tandem wing
Size 5 3 4 2
Drag 4 3 4 2
Manufacturing 2 3 4 3
Maintenance 3 3 3 2
Total 13 42 53 36
Due to its superior performance on the most important figure of merit, the weight, the conventional wing was
chosen as the wing layout.
The next design choice was where to mount the wing. The analysis for this choice is shown in Table 3.
Table 3: Wing Attachment Selection
Wing Attachment
FOM Weight Low Middle High Blended
Size 5 4 4 4 3
Drag 4 4 4 4 3
Manufacturing 2 2 3 2 3
Maintenance 3 2 4 3 3
Total 13 46 54 49 42
The blended wing offers the lowest weight possible due to the fact that much of the weight of the fuselage is
incorporated into the wing as well as exceptional high speed performance. This allows it to outperform the standard
middle attachment and is the reason it was selected. As a consequence of the wing attachment being selected as
blended, the fuselage shape was automatically chosen to be blended as well.
The next step of the configuration selection was to choose the number of fuselages that would be incorporated
into the vehicle. That figure of merit analysis is shown below in Table 4.
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Table 4: Number of Fuselages Selection
Number of Fuselages
FOM Weight Zero One Two Three
Size 5 5 4 3 2
Drag 4 5 4 3 2
Manufacturing 2 5 4 3 2
Maintenance 3 5 4 3 2
Total 13 70 56 42 28
While it may appear that zero fuselages is the best configuration, the reason one fuselage is selected is due to the
fact that zero fuselages does not meet the mission design requirements. If there is no fuselage, there is no room to
store the payload that the vehicle will be dropping.
Next, the type of tail that will be used is analyzed. The analysis of tail types is shown in Table 5.
Table 5: Tail Type Selection
Tail Type
FOM Weight V-tail Conventional H-tail T-tail
Size 5 5 4 3 4
Drag 4 5 4 3 3
Manufacturing 2 3 4 3 4
Maintenance 3 4 3 3 3
Total 13 63 53 42 49
Here, a somewhat unconventional V-tail is seen to be the best configuration choice. This is due to the fact that it
is simpler in structure and performs better than the other options in high speed supersonic flight. As that is the most
strenuous design requirement for the vehicle, that means the major design choices will be made to optimize that
condition.
Once the V-tail configuration is chosen, the placement of the tail is decided. The analysis of tail attachment
locations is shown in Table 6.
Table 6: Tail Attachment Selection
Tail Attachment
FOM Weight One boom Two booms On Fuselage
Size 5 4 3 5
Drag 4 4 3 5
Manufacturing 2 3 2 4
9
Maintenance 3 3 2 4
Total 13 51 37 65
As would be expected, the design clearly favors a tail attached to the fuselage. Booms are used primarily by
helicopters and are not optimal for high speed flight.
The final component to consider is the engines. First, the number of engines must be decided. Table 7 shows the
figure of merit analysis for number of engines.
Table 7: Number of Engines SelectionNumber of Engines
FOM Weight One Two
Size 5 5 4
Drag 4 4 3
Manufacturing 2 4 4
Maintenance 3 3 3
Total 13 58 49
While one engine is lighter, it would have to be larger and heavier than each of the two engines individually in
order to produce the same thrust. This can create structural issues and in general, it is much safer to fly with two
engines in case one engine fails. Therefore, two engines are selected for this design.
In summary, the figure of merits analysis determined that a flying wing aircraft, with a blended wing body shape,
one fuselage, a V-tail mounted to the fuselage, with two engines would be the best design to meet the given
requirements.
C. Final Configuration
The final configuration choices for the vehicle were compiled and a modeling sketch was created using the
OpenVSP software. The result of this sketch can be seen below in Fig. 1. In addition, the location of the 4,000 lbs of
required payload can be seen in Fig. 2. All components except the location of the payload have been de-shaded in
order to emphasize the area where the payload will be located.
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Figure 1: Final Vehicle Configuration
Figure 2: Vehicle Payload Location
III. Weight Sizing Analysis
Now that the configuration for the airplane has been determined, the vehicle must be sized using an iterative
weight sizing analysis. This analysis takes into account the various requirements, mission segments, and design
choices made and allows for an initial value of takeoff weight to be determined. In addition, a constraint analysis is
then performed to determine a proper wing loading and thrust to weight ratio which gives a thrust value for engine
sizing and a wing area for structural sizing.
A. Mission Profile
To begin the weight sizing process, a mission profile was created for use throughout the entire analysis. This
mission profile shows each segment of the flight, the altitude at which each segment was performed, and the range
for each segment of flight. This mission profile will be used for all subsequent analysis regarding the various phases
of flight. A diagram of this mission profile is shown below in Fig. 3.
11
0 200 400 600 800 1000 1200 1400 1600 1800 20000
10000
20000
30000
40000
50000
60000
Start, Taxi, and Takeoff
Climb
Supercruise Dash 1
Delivery
Dash 2AccelerateZoom
Descent 1
Subcruise
Descent 2
Landing
Distance Traveled (nm)
Altit
ude
(ft)
Figure 3: Mission Profile
B. Weight Regression
The next step in the weight sizing process was to create a weight regression based on vehicles of similar
approximate size and design mission. Using these vehicles, a trendline was created in order to determine the values
of the A and B coefficients used to create a relationship between maximum takeoff weight, W TO, and maximum
empty weight, WE. The relationship between these two parameters is given by the following equation:
log10 W E=log10 W ¿−A
B (1)
In addition, in order to incorporate the effects of the improvements of technology by the eventual in-service data of
2025, a technology correction factor of .75 was used to generate the A value for the weight sizing. With this in mind,
the linear regression line created was analyzed to produce values of .815 and .910 for A and B respectively. The
graph showing this regression is displayed in Fig. 4 below.
12
Figure 4: Similar Vehicle Weight
Regression
C. Initial Weight Sizing
After obtaining A and B coefficients, the estimated WTO for the vehicle could be calculated. This is achieved by
creating a step by step analysis for each segment of the mission and approximating the fuel used in each segment.
The assumptions made during this step of the analysis include the rate of climb of the vehicle, RC, the thrust specific
fuel consumption, TSFC, of the engines, and the optimum subsonic cruise altitude and Mach number. All of these
assumptions were chosen to be conservatively within the range of current technology. These assumptions are shown
below in Table 8.
Table 8: Weight Sizing Assumptions
Rate of Climb (ft/s) Rate of Descent (ft/s) TSFC (lb/(lb*hr)) Msubcruise hsubcruise (ft) Acceleration (ft/s2)
2,750 12,000 .95 .8 40,000 9.28
The main purpose of these assumptions was to help with the calculation of the mission fuel fractions. These fuel
fractions are percentages of the takeoff weight which will be used to calculate the total fuel weight of the vehicle.
These assumptions are made in order for the analysis of the vehicle to be made possible. The effect of the choices of
RC and TSFC are analyzed later on during the trade studies. Depending on whether the mission segment is a change
in altitude segment or a constant altitude segment, two different equations for mission fuel fraction are used. These
equations are shown below in Eqns. 1 and 2.
M ff=1
e
E∗TSFCLD
(1)
13
10000 1000001000
10000
100000
Takeoff Weight (lbs)
Empt
y W
eigh
t (lb
s)
M ff=1
e
R∗TSFC
v∗( LD
) (2)
The calculated values of the mission fuel fractions for each segment of flight are shown below in Tables 9a and
9b.
Table 9a: Mission Fuel Fractions
Start Taxi Takeoff Climb Supercruise Dash 1 Zoom
.99 .995 .995 .965 .803 .976 .997
Table 9b: Mission Fuel Fractions (cont.)
Delivery Accelerate Dash 2 Descent 1 Subcruise Descent 2 Landing
.996 .997 .972 .995 .842 .996 .992
These fuel fractions were then multiplied together to get a final mission fuel fraction. This value along with the
chosen values for the fraction of trapped fuel and oil and the fraction of reserve fuel are shown below in Table 10.
Table 10: Additional Fuel Fractions
Mff Mff_tfo Mres
.590 .005 .055
Using these calculated and chosen fuel fractions, the weight of the fuel needed for the flight of the mission was
calculated. Using the initial guess for takeoff weight and subtracting the calculated fuel weight, the known payload
weight, and the crew weight, a value for empty weight of the vehicle was calculated using Eq. 3 below.
W E, calculated=W ¿ , guess−W fuel−W payload−W crew (3)
The empty weight can also be calculated using the initial takeoff weight guess and the previously calculated A
and B coefficients. This calculation is shown in Eq. 4 below.
W E, allowable=10log10 W ¿ , guess−A
B (4)
These two values of WTO are then compared to determine the difference between the two. For the takeoff weight
guess to be an accurate value for the vehicle, the difference between the two calculated empty weights must be very
low. Using Microsoft Excel’s goal seek operator, the two values of WE are converged by varying the initial WTO
guess value. In order to obtain a truly converged value of WE, the lift to drag ratio, L/D, for each segment is also
14
converged during the class I drag polar analysis in the next section. The results of the weight sizing convergence for
this vehicle are shown below in Table 11.
Table 11: Weight Sizing Analysis Results
WTO (lbs) A B WF (lbs) WP (lbs) WC (lbs) WE (lbs)
36,711 .815 .910 19,591 4,000 0 13,121
D. Class I Drag Polar Analysis
In order for the weight sizing analysis to be completed accurately, one factor, the lift to drag ratio, is needed
from a class I drag polar analysis for each segment of the mission. The L/D for each segment is a crucial factor in
the range or endurance equations that determine segment fuel fractions. In order for this analysis to be possible,
factors such as the Oswald efficiency factor, e, the aspect ratio, AR, the thickness to chord ratio, t/c, and the skin
friction coefficient, Cf, are chosen. The choice of AR and t/c are based on military fighter aircraft such as the F-22.
The effect of these choices will be explored later during trade studies on the vehicle. The c and d coefficients needed
to calculate the wetted area of the vehicle are taken from Roskam’s Part II1. Finally, a wing loading, W/S, is roughly
guessed for the purposes of generating a wing area. These values are shown below in Table 12.
Table 12: Drag Polar Assumptions
AR e t/c W/S c d Cf
2.5 .85 .04 98 .2263 .6977 .0026
Using the takeoff weight and the c and d coefficients, the wetted area of the vehicle can be calculated using Eqn. 5.
Swet=10c+d log10 W ¿ (5)
This value of wetted area is then used with the area computed using the wing loading guess and the skin friction
coefficient to calculate a zero lift drag coefficient. This process is shown in Eqn. 6.
CD ,0=C f
Swet
S (6)
For the supersonic cruise segments of the mission, the t/c ratio and the supersonic Mach number are used to
approximate a coefficient of wave drag, CD,wave using the following Eqn. 7:
1 Roskam, Jan. Preliminary Sizing of Airplanes. Lawrence: DARcorporation, 2005. Print.
15
CD ,wave=5.3∗( t
c)
2
√ M2−1
(7)
The coefficient of lift for the vehicle is calculated for each segment using the weight at the beginning of the
segment, the density at that altitude, the velocity of the vehicle, and the wing area approximation as shown in Eqn. 8.
CL=W
.5 ρ v2 S (8)
The induced drag of the vehicle is calculated using the coefficient of lift and the lift factor. The lift factor is
calculated using Oswald’s efficiency factor and the aspect ratio of the aircraft as shown in Eqn. 9.
K1=1
πeAR (9)
The coefficient of drag for the vehicle is then calculated according to Eqn. 10.
CD=CD, 0+CD, wave+K1CL2 (10)
Finally, the lift to drag ratio can be determined by dividing the coefficient of lift by the coefficient of drag. This
final calculation is shown in Eqn. 11.
LD
=CL
CD
(11)
Similarly to the overall WTO, the values for L/D calculated for each segment are then converged with the values
guessed for L/D for use in the weight sizing spreadsheet. Each value must be converged separately and the iterative
convergence process repeated until all values of L/D and the value of WE have been converged at the same time. The
L/D results of this convergence are shown below in Table 13.
Table 13: Lift to Drag Ratios
Climb Supercruise Dash 1 Zoom Deliver
y
Accelerat
e
Dash 2 Descent 1 Subcruis
e
Descent 2
5.58 3.62 5.31 9.31 8.53 9.28 5.10 2.28 9.67 7.67
16
IV. Weight Sizing Trade Studies
In order to solidify some of the assumptions made during the sizing process, trade studies were performed on
some of the key design choices. These trade studies show how the final value of WTO varies as the design variable is
changed.
A. Aspect Ratio Trade Study
One main contributing factor to the design of the vehicle was the chosen value for the aspect ratio. The aspect
ratio has a large impact on the class I drag polar analysis of the aircraft. The variation of the aspect ratio and its
effect on the takeoff weight are shown below in Fig. 5.
1 1.5 2 2.5 3 3.5 430000
35000
40000
45000
50000
55000
60000
Aspect Ratio (~)
Take
off W
eigh
t (lb
s)
Figure 5: Aspect Ratio Trade Study
The graph of takeoff weight versus aspect ratio shows a steady decrease in the takeoff weight as the aspect
ratio is increased. An increased aspect ratio would mean some combination of a decreased wing area or an increased
wing span. The most direct result of varying the aspect ratio is a change in the K 1 value used to calculate the induced
drag in the class I drag polar. As the aspect ratio is increased, the value of K 1 decreases. This results in a decrease in
the coefficient of drag and an increase in the L/D of the vehicle. While this may seem to be an infinitely good result,
the larger and larger aspect ratio puts a much larger stress on the internal structure of the vehicle. As the wing
becomes longer, it becomes very difficult to support the wing, especially in supersonic flight. In addition, due to the
extremely high speeds of supersonic flight, a large L/D is not necessary in order to maintain the lift needed for
steady flight. Thus, for the purposes of this supersonic ULRSV, an L/D of 2.5 was chosen.
B. Thickness to Chord Trade Study
One of the most important phases of the design of this vehicle is the supersonic flight. The supersonic flight
introduces a new source of drag, the wave drag, which as Mach number is increased, begins to greatly impact the
17
overall drag on the vehicle. The equation used to relate the thickness to chord ratio of the wing to the wave drag
created is shown in the class I drag polar discussion section of this report. The variation of t/c and its effect on the
WTO of the vehicle is shown below in Fig. 6.
0.015 0.02 0.025 0.03 0.035 0.04 0.045 0.05 0.055 0.06 0.06530000
35000
40000
45000
50000
55000
Thickness to Chord Ratio (~)
Take
off W
eigh
t (lb
s)
Figure 6: Thickness to Chord Ratio Trade Study
The analysis of WTO versus t/c shows a somewhat quadratic relationship between t/c and takeoff weight. As the
t/c is increased, the WTO increases steadily. This makes sense because as the thickness of the wing is increased,
clearly the weight of the wing will increase as well. This also has implications on the supersonic performance of the
wing. For supersonic flight, wings are desired to be as thin as possible in order reduce the disturbance on the flow at
such high speeds. However, this ratio cannot be so small as to make the wing difficult to manufacture and
potentially impossible to support. Therefore, for the purposes of this vehicle design, a t/c of .04 was chosen for the
vehicle.
C. Vehicle Acceleration Trade Study
Some of the most stressful structural segments are those that require an acceleration of the aircraft. These
segments put the maximum stress on the vehicle and require the greatest output from the engines. By varying the
acceleration requirement for the vehicle, different values of the potential WTO were generated. The results of this
analysis are shown below in Fig. 7.
18
4 5 6 7 8 9 10 11 12 13 1436200
36400
36600
36800
37000
37200
37400
37600
Acceleration (ft/s2)
Take
off W
eigh
t (lb
s)
Figure 7: Vehicle Acceleration Trade Study
The results of this analysis of takeoff weight versus acceleration show a somewhat quadratic relationship
between the two values. As the acceleration requirement in increased, the subsequent converged WTO value is
decreased down to a minimum where it appears to level out. By this analysis, the higher the acceleration, the lower
the takeoff weight. However, higher and higher accelerations put very high stress on the vehicle and place great
demands on the vehicle’s engines. Therefore, an acceleration of 9.28 ft/s2 was chosen to give a low value of WTO
without putting an overly large stress on the vehicle.
D. Thrust Specific Fuel Consumption Trade Study
One of the main sources of weight in the vehicle is the weight due to fuel. Therefore, one of the most important
parameters chosen for the design of this vehicle was the thrust specific fuel consumption, TSFC, of the engines. The
higher the value of TSFC, the more rapidly the fuel is consumed by the engines and the more the range is reduced.
Therefore, an engine design team will always strive to decrease the TSFC of the engines they are creating.
However, due to the design mission of this vehicle to fly in high altitude supersonic flight, the TSFC for the engine
is unavoidably large. Current technology has made great strides in the reduction of TSFC in transonic flight but in
order to maintain supersonic flight, the fuel consumption of an aircraft is still very high. To demonstrate the large
impact that the TSFC has on the WTO, a trade study analysis was done of TSFC. The results of this analysis are
shown below in Fig. 8.
19
0.7 0.75 0.8 0.85 0.9 0.95 1 1.05 1.1 1.15 1.220000
25000
30000
35000
40000
45000
50000
55000
60000
Thrust Specific Fuel Consumption (lb/(lb*hr))
Take
off W
eigh
t (lb
s)
Figure 8: Thrust Specific Fuel Consumption Trade Study
As can be clearly seen from this graph, the TSFC has an enormous impact on the converged value of W TO. When
the value of TSFC increases from .75 to .1.15, the value of WTO more than doubles from 25,000 lbs to over 50,000
lbs. This relationship is why the focus of engine design is always on reducing the TSFC as much as possible.
However, for this design, in order to take into account the high fuel burn of supersonic flight, a TSFC of .95 was
chosen for design analysis.
E. Supercruise Mach Number Trade Study
The final design point considered for the trade study analyses of this vehicle design was the choice of supersonic
cruise Mach number. As discussed previously, the supersonic requirement for this vehicle results in a large fuel burn
and reduced overall range of the vehicle. In order to demonstrate the large effect of the fuel weight on the W TO of the
aircraft, the supersonic cruise Mach number was varied and then the WTO was re-converged. The results of this
analysis are shown below in Fig. 9.
20
1 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 1.9 234000
35000
36000
37000
38000
39000
40000
41000
Supercruise Mach Number (~)
Take
off W
eigh
t (lb
s)
Figure 9: Supercruise Mach Number Trade Study
The graph of takeoff weight versus supercruise Mach number shows a very clear quadratic relationship. With a
higher supercruise Mach number though the aircraft is flying the same distance over a shorter amount of time, the
amount of fuel necessary for this flight goes up considerably. This results in a 4,000 pound increase between a cruise
Mach number of 1.5 and 1.9. For this parameter, however, the design requirements for the vehicle clearly specified a
supercruise Mach number of 1.5. Therefore, the requirements of the customer outweigh any efficiency gains from
flying at a different speed.
V. Constraint Analysis
The goal of this analysis is to further the design of the uninhabited long range strike vehicle previously created
during the weight sizing process. In order to determine important design features such as the thrust to weight ratio
and the wing loading of the vehicle, a constraint analysis was performed on the initial design. These two ratios are
important parameters because using these values as well as the takeoff weight from the weight sizing process, the
sea level thrust required to power the vehicle and the wing area of the vehicle can be determined. With the takeoff
weight, the empty weight, the thrust required, and the wing area of the vehicle as well as conceptual configuration
choices, specific decisions about engines, internal structure, and materials to be used can be considered in order to
move into a more detailed design.
For each mission segment, a constraint analysis was performed to determine the relationship between the thrust
to weight ratio and the wing loading for that segment of the flight. The primary foundation for this analysis is the
energy based constraint equation. This equation is shown below in Eqn 12.
21
T SL
W ¿
=βα { qS
βW ¿[K1( nβ
qW ¿
S )2
+K2( nβq
W ¿
S )+CD0+ R
qS ]+ 1V
ddt (h+ V 2
2 g0)} (12)
The energy based constraint equation applies to all segments of the flight. However, in order to make the analysis
easier, simplifying assumptions are made for each case in order to simplify the equation to a more manageable form.
For example, in all segments of flight except takeoff and landing, R = 0 because the aircraft is not on the ground and
there is no ground friction. In order to do the constraint analysis, several assumptions made during the weight sizing
process were reused. These include the vehicle aspect ratio, the zero lift drag coefficient, the Oswald’s efficiency
factor, and the first and second order drag polar coefficients. The aspect ratio of 2.5 was chosen because both the F-
22 Raptor and the F-35 Lightning have similar aspect ratios. The F-22 has an aspect ratio of 2.35 while the F-35 has
an aspect ratio of 2.662. Both of these aircraft are similar in design and have the capability to fly at high supersonic
speeds. The wing area, the lift factor, and the zero lift drag coefficient are taken from the previous analysis done
during the class I drag polar.
The other factors of great importance for this analysis are the thrust lapse and weight correction. The thrust lapse
is calculated using the density ratio of the density at the altitude of that segment to the density at sea level as shown
in Eqn. 13. The thrust lapse at altitude is then calculated using this density ratio and the Mach number of the desired
segment as shown in Eqn. 14. The weight correction, beta, is defined as the weight at the start of the segment over
the takeoff weight as shown in Eqn 15.
σ= ρρSL
(13)
α= TT SL
=.72 [ .88+.245 (|M−.6|)1.4 ] σ .7 (14)
β= WW ¿
(15)
These values are used in each segment of the flight to calculate the thrust to weight values needed to maintain
stable flight. For the purposes of this design analysis, the final design point was required to be at a thrust to weight
ratio between .6 and 1.2 and a wing loading between 60 and 100 pounds per square foot.
A. Takeoff
The first segment of the vehicle operation that was analyzed was the takeoff performance of the vehicle. Two
different takeoff possibilities were analyzed: takeoff with friction and takeoff assuming that friction is negligible.
First, the case that assumes that the thrust force is much greater than the drag due to friction was analyzed. For this
case, the overall energy based constraint equation is reduced to the following form shown in Eqn. 16:
2 Hunter, Jamie. Jane's All the World's Aircraft: In Service: 2012-2013. Coulsdon: IHS Jane's, 2012. Print.
22
T SL
W ¿=β2
αk¿
2
sG ρ g0CL ,max(W ¿
S ) (16)
The takeoff performance was analyzed at an altitude of 5,000 ft on a 90° F day, the takeoff distance was given to
be 10,000 ft and the takeoff speed safety factor was chosen to be 1.2. The values used for this analysis are shown in
Table 14.
Table 14: Simple Takeoff Analysis Values
α β CL,max, TO rho (slugs/ft3) kTO STO (ft)
.608 .985 1.8 .001866 1.2 10,000
After performing this analysis, the thrust to weight is shown to vary from .1 at 50 lbs per square ft to .4 at 170 lbs
per square ft. This shows that a takeoff without friction has very little impact on the overall performance
requirements of the vehicle. The takeoff case does not drive the design point decision.
The assumption that friction plays a very small role in the takeoff performance is a very oversimplifying one.
Therefore, an analysis of the takeoff was performed that also takes into consideration the rolling friction. For this
analysis, the energy based constraint equation was modified to the following:
T SL
W ¿=
βα {ξ¿
qβ ( S
W ¿)+μ¿+
1g0
dVdt } (17)
The variable, ξTO, is defined as shown in Eqn. 18.
ξ¿=(CD+CD , R−μ¿CL ) (18)
In this analysis, the most important chosen factor is the ground friction coefficient. This value was chosen to
be .025 based on data for various surfaces taken from Roskam.3 The values used for this analysis are shown below in
Table 15.
Table 15: Frictional Takeoff Analysis Values
α β CL,max, TO rho (slugs/ft3) μ dv/dt (ft/s2) q (lbs/ft2) CD,R
.608 .985 1.8 .001866 .025 4 44.92 .0458
The results of this analysis proved that the frictionless assumption drastically changes the resulting thrust to
weight ratio required. Whereas the frictionless case produced thrust to weight ratios ranging from .1 to .4, the case
3 Roskam, Jan. Preliminary Sizing of Airplanes. Lawrence: DARcorporation, 2005. Print.
23
including friction resulted in thrust to weight ratios from 1.3 at 50 lbs per square ft wing loading to .55 at 170 lbs per
square ft wing loading. This relationship shows that at lower wing loading, the frictionless assumption is very poor,
but at higher values of wing loading, the error due to the assumption decreases dramatically. The comparison of
these two curves is plotted below in Fig. 10.
50 70 90 110 130 150 1700
0.2
0.4
0.6
0.8
1
1.2
1.4
Simple TakeoffFriction Takeoff
Wing Loading at Takeoff (lbs/ft2)
Thru
st to
Wei
ght a
t Sea
Leve
l Tak
eoff
(~)
Figure 10: Takeoff Assumption Comparison
B. Climb and Descent
The next important flight segment to be considered was the climb and descent of the aircraft. For the segments of
flight involving constant speed climb or descent, the energy based constraint equation was simplified to the
following form shown in Eqn. 19:
T SL
W ¿=
βα {K1
βq (W ¿
S )+K2+CD0
βq (W ¿
S )+
1V
dhdt } (19)
The necessary assumptions to perform this analysis were the vehicle speed and the vehicle climb rate. The
vehicle is assumed to be in a state where time to climb is not important. Therefore, the climb speed was chosen to be
250 knots and the both descent speeds were chosen to be 200 knots in order to reduce the thrust necessary. The rate
of climb was chosen to be 2,750 feet per minute. As the F-22 Raptor has a potential climb rate of over 50,000 feet
24
per minute4, this value is well within the possible range for an aircraft of similar performance and is chosen to be
low in order to reduce the thrust to weight ratio necessary for this segment of flight. The rate of descent was chosen
to be 12,000 feet per minute. The values used for the climb, descent 1, and descent 2 segments of flight are shown
below in Tables 16, 17, and 18.
Table 16: Climb Analysis Values
α β v (ft/s) rho (slugs/ft3) dh/dt (ft/s) q (lbs/ft2)
.386 .98 421.95 .000974 45.83 86.73
Table 17: Descent 1 Analysis Values
α β v (ft/s) rho (slugs/ft3) dh/dt (ft/s) q (lbs/ft2)
.192 .685 337.56 .000408 -200 23.25
Table 18: Descent 2 Analysis Values
α β v (ft/s) rho (slugs/ft3) dh/dt (ft/s) q (lbs/ft2)
.426 .522 337.56 .001267 -200 72.16
The resulting thrust to weight values for the climb segment increased linearly from .57 at 50 lbs per square ft
wing loading to 1.05 at 170 lbs per square ft wing loading. The values of thrust to weight for the first descent
increased rapidly from -1.28 to .66 while the values for the second descent increased from -.60 to -.48. The reason
for the difference is due to the second descent occurring after the subcruise phase and at a much lower altitude. The
lighter aircraft and the lower density make the requirements much lower for the vehicle. As these segments of climb
and descent are only to change altitude for the mission and do not need to be executed in a rapid timeframe, the
values were intentionally chosen so that this segment of flight would not drive the design.
C. Cruise
Based on the weight sizing analysis, the phases of flight that consume the most fuel are the supersonic and
subsonic cruise. Therefore, it is important to analyze these flight segments to ensure that the thrust to weight ratio
required does not put a high strain on the vehicle over a long period of time. Since the cruise is assumed to be steady
level flight, both of the terms in the energy based strain equation involving change in velocity or change in height
become zero and the equation simplifies to the following form shown in Eqn. 20. In addition the two supersonic
dash segments are also analyzed using this equation.
4 Hunter, Jamie. Jane's All the World's Aircraft: In Service: 2012-2013. Coulsdon: IHS Jane's, 2012. Print.
25
T SL
W ¿=
βα {K1
βq (W ¿
S )+K2+CD0
βq (W ¿
S )} (20)
The only assumption that is made for the either cruise segment is the subsonic cruise takes place at a chosen
altitude and Mach number. For the purposes of this mission, an altitude of 40,000 feet and Mach .8 were chosen.
The values for each of these segments of flight are shown in tables 19, 20, 21 and 22 below.
Table 19: Supercruise Analysis Values
α β v (ft/s) rho (slugs/ft3) q (lbs/ft2)
.178 .945 1452.11 .000285 300.03
Table 20: Dash 1 Analysis Values
α β v (ft/s) rho (slugs/ft3) q (lbs/ft2)
.163 .748 1936.15 .000285 533.38
Table 21: Dash 2 Analysis Values
α β v (ft/s) rho (slugs/ft3) q (lbs/ft2)
.207 .713 1936.15 .000285 533.38
Table 22: Subcruise Analysis Values
α β v (ft/s) rho (slugs/ft3) q (lbs/ft2)
.244 .680 774.46 .000585 175.49
The values of thrust to weight ratio for the supersonic cruise that resulted from this analysis varied from .73
to .55 and increased again to .61 as the wing loading was increased from 50 to 170 lbs per square ft. The subsonic
cruise had an even smaller range from .34 down to .29 and increasing back to .36. The values for the thrust to weight
ratio of the dash 1 segment decreased from 1.22 to .50 and the values for the thrust to weight of the dash 2 segment
decreased from .95 to .38. As the design range is between .6 and 1.2, it is clear that neither of the cruise mission
segments has a large impact on the design point selection while the dash segments would only have influence on the
design point at low wing loading.
D. Zoom and Acceleration
The mission segment that involves the greatest amount of thrust for this mission was the acceleration segment.
The vehicle was required to increase its speed from Mach .85 to Mach 2 in two minutes. In order to achieve this, a
26
substantial dive was needed to decrease the thrust load placed on the engines. Without a dive maneuver, the thrust
required for this acceleration would have far exceeded the design requirements for the vehicle. The zoom maneuver,
on the other hand, required a substantial increase in altitude in order to rapidly slow down the vehicle. For these
purposes, the energy based strain equation was modified to include both a change in altitude as well as a change in
velocity. The resulting equation is shown below in Eqn. 21:
T SL
W ¿=
βα {K1
βq (W ¿
S )+K2+CD0
βq (W ¿
S )+
1V
dhdt
+1g0
dVdt } (21)
For these segments of flight, the critical assumptions that are made include the velocity, the rate of climb, and
the acceleration. As this analysis can only be done using a single velocity, the velocity was chosen as the average
between the values of Mach 2 and Mach .85. This resultant velocity was 817 knots. The acceleration was derived
from a simple calculation of the change in velocity over the given two minutes to be 9.28 ft/s 2. Finally, the rate of
climb was given in the requirements to be 200 fps.
Table 23: Zoom Analysis Values
α β v (ft/s) rho (slugs/ft3) dv/dt (ft/s2) q (lbs/ft2) dh/dt (ft/s)
.174 .724 1379.51 .000285 -9.28 270.78 200
Table 24: Acceleration Analysis Values
α β v (ft/s) rho (slugs/ft3) dv/dt (ft/s2) q (lbs/ft2) dh/dt (ft/s)
.174 .716 1379.51 .000285 9.28 270.78 -200
Taking rate of climb to be positive and acceleration to be negative, the values of thrust to weight ratio for the
zoom segment of flight were calculated to range from .04 down to -.15. This shows that the deceleration has a much
greater impact on the thrust required than the change in height. For the acceleration flight segment, a negative rate of
climb and positive acceleration produced thrust to weight values ranging from 1.23 at 50 lbs per square ft wing
loading decreasing down to 1.04 at 170 lbs per square ft. These values are very important to the overall analysis
because it can be clearly seen that this segment of flight will be very influential in the determination of the overall
design point. The acceleration puts a great load on the vehicle’s engines and it is only through a dive maneuver that
this segment of flight is able to be contained within the required parameters.
E. Delivery
When designing a vehicle for a specific purpose such as this uninhabited long range strike vehicle, one of the
obviously important segments of the mission is the segment involving the actual execution of the mission objective
itself. In this case, this involves releasing a payload weapon at a desired military target. For the purposes of this
27
analysis, the payload delivery segment has been modeled as a constant speed and constant altitude turn. However,
for the purposes of assuming a worst case scenario, it is assumed that the vehicle does not deliver its payload. The
result of these assumptions is the following energy based strain equation shown in Eqn. 22:
T SL
W ¿=
βα {K1 n2 β
q (W ¿
S )+K2 n+CD0
βq (W ¿
S ) } (22)
The major difference with this equation and the previous equations used for steady level flight is the inclusion of
the load factor. In all previous cases, the load factor, n, was assumed to be approximately one and therefore not
important in the calculation of the thrust to weight ratios. In this case, the execution of a turning maneuver makes
that assumption invalid and the load factor must be included. The load factor is defined by the following equation
shown in Eqn. 23:
n= 1cosθ
(23)
Theta is defined as the turn bank angle in degrees. Therefore, the larger the turn bank angle, the greater the load
factor and the greater the resultant stress on the vehicle. The design requirements for the vehicle initially specified a
load factor of two, but indicated that this parameter could be adjusted in order to maintain the desired thrust to
weight and wing loading.
Table 25: Delivery Analysis Values
α β v (ft/s) rho (slugs/ft3) n q (lbs/ft2)
.176 .721 822.86 .000362 1.6 122.51
The initial value of two for load factor proved to be excessive for the vehicle and produced thrust to weight
values that were outside the desired range. Therefore, in order to obtain values that were more suitable, the load
factor was decreased from 2 to 1.6. This modification resulted in thrust to weight values that increased linearly
from .71 up to 1.68 as wing loading increased. The intersection of this curve with the curve previously determined
from the acceleration segment created the corner where the design point was later placed.
F. Approach
The last segment of flight, the approach, is important to the mission because although the thrust to weight value
is not a factor, the calculated wing loading for the approach defines the absolute maximum wing loading possible for
the vehicle. To determine this value, the equation for stall speed was rearranged to the following form in Eqn. 24:
28
W ¿
S=
ρ vapp2C L,max
2 kapp2 β
(24)
The stall speed has been replaced by the approach speed divided by the approach safety factor. The approach
safety factor is an important parameter and has been chosen to be 1.3. The other important assumptions for this
analysis are the approach speed and the maximum lift coefficient of the vehicle. The approach speed is given by the
requirements to be 170 knots. However, this value proved to be slightly large when examining the resultant wing
loading value and was reduced to 160 knots in order to provide a more reasonable value. The maximum coefficient
of lift on approach was assumed to be 2.2 based on data taken from Roskam about the increase in maximum C L due
to non-clean configurations.5 The vehicle was assumed to land at the same location and conditions that it initially
took off from. The values for this approach analysis are shown in Table 25.
Table 26: Approach Analysis Values
β CL,max,L vapp (ft/s) rho (slugs/ft3) kapp
.518 2.2 270.05 .001866 1.3
The result of this analysis of the approach of the vehicle was a maximum wing loading of 170.86 lbs per square
ft. This high value of wing loading means that there is a wide range of possibilities for design points and the landing
segment of flight will not have a heavy impact on this design point.
G. Service Ceiling
The final energy based constraint that was analyzed was the service ceiling of the vehicle. It is important to
know the maximum altitude possible at specific velocities for the purpose of maneuverability as well as the risk of
exceeding the service ceiling and approaching the dangerous absolute ceiling. The form of the energy based
constraint equation used to analyze this requirement is no different from the one used earlier to analyze the constant
speed climb. The equation is shown below in Eqn. 25:
T SL
W ¿=
βα {K1
βq (W ¿
S )+K2+CD0
βq ( W ¿
S )+
1V
dhdt } (25)
What makes this analysis different from the original climb analysis is the rate of climb used for the analysis. The
service ceiling for a military aircraft is defined to be the altitude at which the vehicle’s rate of climb is equal to 100
5 Roskam, Jan. Preliminary Sizing of Airplanes. Lawrence: DARcorporation, 2005. Print.
29
feet per minute. For this analysis, the desired ceiling has been defined to be 60,000 feet and the Mach number for
this ceiling has been given as Mach 2.0. At that altitude and Mach number, the velocity is calculated to be 1,147
knots. The values used for this analysis are shown in Table 26.
Table 27: Service Ceiling Analysis Values
α β v (ft/s) rho (slugs/ft3) dh/dt (ft/s) q (lbs/ft2)
.175 .945 1936.15 .000224 1.67 419.44
Using these values, the resultant thrust to weight values required to reach this service ceiling range from .95
down to .57 as wing loading is increased. Therefore, the given service ceiling requirement is not a factor when
considering the overall design point.
H. Design Point
The purpose of this entire constraint sizing analysis was to determine a point on the graph of wing loading vs
thrust to weight ratio that satisfied all the individual mission segment requirements. This design point would
minimize the thrust to weight ratio necessary while maximizing the wing loading. This point is the most design point
because a minimized thrust to weight ratio expands the range of possible engines that can provide the necessary
thrust. The less thrust that is required, the lighter the engine can be. In addition, a maximized wing loading
minimizes the necessary wing area required for the vehicle and reduces the structural load placed on the fuselage as
well as the inner spars and ribs needed. After doing the energy based constraint analysis on all of the segments of
flight, the two segments that define this design point are shown to be the acceleration and the delivery of the
payload. The intersection of these two curves defines the location with the minimum thrust to weight ratio while still
attempting to maximize the wing loading. Therefore, for this constraint analysis, the resultant thrust to weight ratio
was determined to be 1.06 with a wing loading of 98 lbs per square ft. Using these values as well as the initially
determined takeoff weight value of 36,711 lbs, the sea level thrust necessary and the wing area of the vehicle were
calculated to be 39,031 lbs and 375.7 ft2 respectively. All of the different thrust to weight ratio curves as well as the
design point can be seen below in Fig. 11.
30
Figure 11: Constraint Analysis
VI. Constraint Analysis Sensitivity Studies
Now that a design point has been determined for the vehicle, the requirements of the design call for sensitivity
studies in order to determine the impact of both performance requirements as well as the assumptions made
throughout the analysis.
A. Descent Rate Trade Study
The first performance parameter that was analyzed was the descent rate during the accelerated dive of the
vehicle. The acceleration segment of the flight was one of the determining factors of the design point. Therefore, the
descent rate was chosen in order to determine how relaxing or increasing the dive performed would affect the
overall design of the vehicle. The result of this trade study is shown below in Fig. 12.
31
50 70 90 110 130 150 170
-1.5
-1
-0.5
0
0.5
1
1.5
2Simple Takeoff
Friction Takeoff
Climb
Supercruise
Dash 1
Zoom
Delivery
Acceleration
Dash 2
Descent 1
Subcruise
Descent 2
Landing
Service Ceiling
Design PointWing Loading at Takeoff (lbs/ft2)
Thru
st to
Wei
ght a
t Sea
Lev
el T
akeo
ff (~
)
50 70 90 110 130 150 170
-1.5
-1
-0.5
0
0.5
1
1.5
2
150 ft/s
175 ft/s
200 ft/s
225 ft/s
250 ft/s
Wing Loading at Takeoff (lbs/ft2)
Thru
st to
Wei
ght a
t Sea
Lev
el T
akeo
ff (~
)
Figure 12: Descent Rate Trade Study
The results of this sensitivity study show the strong impact that the descent rate has on the overall thrust to
weight value of the acceleration segment. The steeper the dive, the greater the acceleration due to gravity and the
less acceleration that the engines themselves are required to put out. Therefore, from a performance perspective, it is
always desireable to dive as steeply as possible in order to both reduce the time necessary for the desired
acceleration as well as reduce the necessary output of the engines of the vehicle.
B. Load Factor Trade Study
The other mission segment that defined the design point for this vehicle was the delivery of the payload modeled
as a constant speed and constant altitude turn. The driving factor in the thrust to weight ratio of this analysis was the
load factor of the vehicle. The greater the load factor, the steeper the turn being performed and the greater the load
on the vehicle itself. The sensitivity study with respect to the load factor is shown in Fig. 13 below.
32
50 70 90 110 130 150 170
-2
-1
0
1
2
3
4
0.8
1.2
1.6
2
2.4
Wing Loading at Takeoff (lbs/ft2)
Thru
st to
Wei
ght a
t Sea
Lev
el T
akeo
ff (~
)
Figure 13: Load Factor Trade Study
This sensitivity study shows just how large an impact the load factor has on the resulting thrust to weight values.
For the initially suggested load factor of two, the maximum wing loading of the vehicle would be very small in order
to maintain the desired maximum of 1.2 on the thrust to weight ratio. Increasing the load factor to 2.4 results in a
very steep curve with thrust to weight ratios well beyond the acceptable range. Therefore, for this design, the load
factor was decreased to 1.6 in order to expand the range of possible wing loading values that would meet the
specified requirements.
C. Maximum Lift Coefficient on Approach Trade Study
One of the most important assumptions in this analysis was the assumption regarding the maximum lift
coefficient during the final approach and landing of the vehicle. This assumption is important because the approach
segment of flight determines the maximum wing loading possible for the vehicle. The values of the lift coefficient
vary depending on the amount of extra surfaces and wing area that are added by the use of devices such as flaps and
slats. The greater the wing area that is increased during landing, the larger the resulting maximum lift coefficient
will be. A sensitivity study was performed on this lift coefficient in order to determine the magnitude of its effect on
the resulting wing loading value. The results of this sensitivity study are shown below in Fig. 14.
33
50 70 90 110 130 150 170 190 210 230
-1.5
-1
-0.5
0
0.5
1
1.5
2
2.5
1.6
1.9
2.2
2.5
2.8
Wing Loading at Takeoff (lbs/ft2)
Thru
st to
Wei
ght a
t Sea
Lev
el T
akeo
ff (~
)
Figure 14: Maximum Lift Coefficient on Approach Trade Study
The results of this sensitivity confirm that the lift coefficient on approach has a strong impact on the maximum
wing loading possible for the vehicle. An increase in the lift coefficient of .3 results in an increase in the maximum
wing loading by approximately 23. For this design analysis, a lift coefficient of 2.2 was chosen due to data shown in
Roskam detailing the lift coefficient due to flaps at landing.
D. Takeoff Distance Trade Study
The final design assumption that was analyzed for a sensitivity study was the requirement for takeoff distance.
While the takeoff segment did not have an impact on the design point chosen for the vehicle, the length of takeoff is
still a very important parameter as it defines the set of possible runways this vehicle is capable of using. The shorter
the necessary distance for takeoff, the greater possible takeoff and landing locations the vehicle can use. This can be
highly desirable for possible uses on an aircraft carrier or rapidly assembled bases near military front lines. The
results of this sensitivity study are shown below in Fig. 15.
Figure 15: Takeoff Distance Trade Study
The results of this sensitivity study show that the required distance for takeoff does have a strong impact on the
thrust to weight ratio necessary for the vehicle. The shorter the allowable takeoff distance, the greater the slope of
the relationship between wing loading and thrust to weight ratio. Should the takeoff distance be reduced even
34
further, it could become a design point consideration. However, for the purposes of this design analysis, the takeoff
performance was not a priority and so a distance of 10,000 feet was used to ensure that the takeoff performance did
not affect the overall design choices.
VII. Component Design
After performing the constraint analysis on the desired vehicle, the next step in the design process is to begin
designing individuals components of the overall vehicle. Each component was designed using a specific process
detailed in Roskam’s Part II design book. Previous analysis and configuration choices resulted in a vehicle with one
fuselage, a conventional, mid mounted wing, and a v-tail. This paper will explain the design choices made and show
their impact on the final design of each component. Throughout the report, many of the design choices made were
taken from Roskam’s data regarding the F-16 military fighter. This is due to the fact that the F-16 shares a similar
speed and capability and overall size to that of the vehicle designed for this long range strike mission.
VIII. Fuselage Design
The primary component of this supersonic vehicle that must be designed first is the fuselage. The preliminary
configuration choices resulted in a single fuselage aircraft. This fuselage would contain the weapons payload, the
avionics, and as much of the necessary mission fuel as possible.
35
50 70 90 110 130 150 170
-1.5
-1
-0.5
0
0.5
1
1.5
2
5,000 ft
7,500 ft
10000 ft
12,500 ft
15,000 ft
Wing Loading at Takeoff (lbs/ft2)
Thru
st to
Wei
ght a
t Sea
Lev
el T
akeo
ff (~
)
A. Weight
The first step in the design process of the fuselage involved compiling a list of all the various components that
would be placed inside the fuselage. The fuselage must be sized in order account for all the weights and volumes of
these components. In order to determine the weight of the avionics equipment necessary in the aircraft, a simple
relationship shown in Eqn. 26 is used. The density of the avionic equipment is assumed to be 30 lbs per square feet.
The list of these weights and sizes is shown in Table 27 below.
W avionics
W E
=.03 (26)
Table 28: Fuselage Component Weight and Volume
Weight (lbs) Volume (ft3)
Avionics 395 13.2
Military Payload 4,000 42.9
Mission Fuel 19,657 408.8
As can be seen from the table, the mission fuel requirement easily dominates both the weight and the volume
requirements. The avionics weight and volume were taken from simple relations from Raymer’s design book based
on the empty weight of a fighter aircraft which can be used for preliminary design purposes. The weight of the
avionics was taken to be 3% of the empty weight of the aircraft and the density of the avionics was taken to be 30
lbs/ft3.6 The military payload weight was given by the requirements in the early design phase of the aircraft while the
volume was taken from the known dimensions of a GBU-32 smart bomb7. Finally, the fuel volume needed for the
aircraft was calculated using the previously known fuel weight of 19,657 lbs and the density of JP-8 military fuel
taken to be .775 kg/L8.
B. Design Choices
Using the known volumes of the various components inside the fuselage, the fuselage cross section and length
can be considered. The most important parameter in the design of the fuselage itself is fineness ratio. This ratio is
defined as the length of the fuselage divided by the diameter. Using Roskam’s table of values for fineness ratio
found in Table 4.1 of Part II of his design book series, a fineness ratio of 10 was selected for this aircraft9. Due to the
supersonic requirements of the vehicle’s mission, a longer, thinner fuselage section is desired because it will
6Raymer, Daniel P. Aircraft Design: A Conceptual Approach. Reston, VA: American Institute of Aeronautics and Astronautics, 1999. Print.7 "Joint Direct Attack Munition (JDAM) GBU-29, GBU-30, GBU-31, GBU-32."Joint Direct Attack Munition (JDAM) GBU-31. N.p., n.d. Web. 6 Nov. 2014. http://fas.org/man/dod-101/sys/smart/jdam.htm. 8 Schmigital, Joel, and Jill Tebbe. JP-8 and Other Military Fuels. Rep. N.p., 12 Jan. 2011. Web. 8 Nov. 2014. www.dtic.mil%2Fcgi-bin%2FGetTRDoc%3FAD%3DADA554221. 9 Roskam, Jan. Preliminary Configuration Design and Integration of the Propulsion System. Lawrence, Kan.: DARcorporation, 2004. Print.
36
produce less drag in the high speed flow. In addition to this fineness ratio, Roskam also gives values for the
structural thickness of the fuselage wall. This chosen thickness of 2 inches must be taken into account when the
fuselage itself is designed and modeled.
C. Fuselage Model
Using the internal component volumes as well as the parameters taken from Roskam’s data10, a three-view of one
potential fuselage design was created using SolidWorks modeling software. These views are shown in Fig. 16, Fig.
17, and Fig. 18 below. All dimensions shown are in feet.
Figure 16: Fuselage Top View
Figure 17: Fuselage Side View
10 Roskam, Jan. Preliminary Configuration Design and Integration of the Propulsion System. Lawrence, Kan.: DARcorporation, 2004. Print.
37
Figure 18: Fuselage Front View
D. Final Fuselage Design Summary
As the three views of the final fuselage model show, a circular cross section with a diameter of 6 feet was chosen
for the main section of the fuselage. Using this choice and the fineness ratio, the final length of the fuselage can be
easily calculated to be 60 feet long. This is a reasonable value because it is comparable to current military aircraft
such as the F-22 Raptor which has a length of 72 feet11. The entire fuel necessary for the mission has been placed
inside the fuselage, thus allowing the wings to be of a minimal thickness and overall weight. This fuel is stored in
one large central tank in the center of the aircraft. This tank has a diameter of 5 feet and a length of 22 feet. These
dimensions give a tank volume of 431.9 ft3 which is more than adequate to store the 19,657 lbs of fuel. The military
payload of the four GBU-32 bombs has been placed near the rear of the aircraft, with the four bombs being stacked
vertically on top of one another for rapid deployment in a combat situation. The avionics of the aircraft has been
placed at the front of the fuselage in place of a cockpit. Finally, the small object placed between the avionics and the
main fuel tank is the Jet Fuel Starter, JFS, which is used to power up the vehicle’s engines until they can maintain
their rotation themselves.
11 Hunter, Jamie. Jane's All the World's Aircraft: In Service: 2012-2013. Coulsdon: IHS Jane's, 2012. Print.
38
IX. Wing Design
Now that the fuselage has been designed, the next component to be designed was the wing. The wing provides
the vast majority of the lift for this aircraft as well as being the location of the vehicle flap and ailerons as well as
the engines which are not included in this version of the design. The preliminary configuration choices previously
decided that this wing would be a traditional wing mounted in the middle of the fuselage.
A. Configuration Choices
Throughout the wing design process, many assumptions and design choices were made using historical data
taken from Roskam’s design book. While these choices do not have numerical explanations, they have been
previously verified by design engineers and analysts using complex finite element analysis, FEA, as well as
computational fluid dynamics, CFD. Therefore, it possible to use these assumptions and values created for other
aircraft in the design of this vehicle provided that the two vehicles share similar traits.
Due to the mission requirements of the vehicle, the wing was chosen to be a cantilevered wing mounted the
middle of the fuselage. The mid wing attachment point was selected due to its strong supersonic performance with
respect to minimizing drag on the aircraft.
B. Airfoil Selection
One critically important factor in the design of the wing is the airfoil chosen to be the cross section of the wing
along the span. This airfoil drives the vehicle’s lift, drag, and moment response through all phases of flight. For the
purposes of this supersonic strike vehicle, the NACA 64-204 airfoil was chosen. This design choice was based on
similar aircraft such as the F-22 Raptor which used this type of airfoil in their design. This airfoil was analyzed in
the XFOIL program to determine these important responses. The graphs of these responses are shown in Figs. 19,
20, 21, and 22.
-4 -2 0 2 4 6 8 10 12 14-0.2
0
0.2
0.4
0.6
0.8
1
1.2
Angle of Attack (°)
Coeffi
cient
of L
ift (~
)
Figure 19: Coefficient of Lift versus Angle of Attack for NACA 64-204
39
The coefficient of lift versus angle of attack shows the .177 offset of the c l due to camber. The initial portion of
the graph shows a very linear relationship with a dc l/dα of .1098. The stall characteristics of the airfoil can be seen
beginning around 8 degrees angle of attack. Immediately the cl decreases and becomes very unsteady.
-4 -2 0 2 4 6 8 10 12 140
0.02
0.04
0.06
0.08
0.1
0.12
0.14
0.16
0.18
Angle of Attack (°)
Coeffi
cient
of D
rag
(~)
Figure 20: Coefficient of Drag versus Angle of Attack for NACA 64-204
The coefficient of drag versus angle of attack response shows very favorable drag at low angles of attack.
Between -2 and 6 degrees angle of attack, the coefficient of drag is nearly constant at a value of .004. This means
that the cl can be increased for added lift without a drastic penalty in the increase in drag. At an angle of attack
beyond 6 degrees, the drag begins to increase dramatically and at the stall point, makes a near vertical increase.
-4 -2 0 2 4 6 8 10 12 14
-0.08
-0.07
-0.06
-0.05
-0.04
-0.03
-0.02
-0.01
0
Angle of Attack (°)
Coeffi
cient
of M
omen
t
Figure 21: Coefficient of Moment about the Leading Edge versus Angle of Attack for NACA 64-204
The coefficient of moment about the leading edge of the vehicle is shown to be negative regardless of the angle
of attack chosen. This is a desirable outcome because it means that when the vehicle will naturally resist any upward
40
change in its angle of attack and attempt to prevent increasing angle of attack up to the stall region. For the range of
angles of attack which will be used by this vehicle, the Cm,LE is nearly constant at a value of -.043.
0 0.02 0.04 0.06 0.08 0.1 0.12 0.14
-0.2
0
0.2
0.4
0.6
0.8
1
1.2
Coefficient of Drag (~)
Coeffi
cient
of L
ift (~
)
Figure 22: 2-D Drag Polar for NACA 64-204
Finally, the drag polar for the NACA 64-204 airfoil shows a very high L/D ratio for all values of c l up to almost
one. This behavior means that the range performance will be very strong at all angles of attack before stall.
However, in supersonic flight, the velocity is so high that in order to produce the lift necessary for steady level
flight, the cl does not need to be very high. Therefore, to maintain level flight, a lower angle of attack than the
optimum will be used.
C. Wing Geometry Specification
Having decided upon the airfoil shape to be used for the wing, the next step is to determine the geometric
properties of the wing. These properties are taken from previous sizing and constraint analysis and Roskam’s
historical data as well as design choices with regards to drag and vehicle control. The chosen specifications are
displayed below in Table 28.
Table 29: Main Wing Specifications
structure placement airfoil Area (ft2) AR Span (ft) Sweep,c/4 (°) t/c taper incidence (°) dihedral (°)
cantilevered mid-wing NACA 64-204 374.0 2.5 30.6 45 .04 .3 0 0
The properties such as the wing area, aspect ratio, span of the wing, and thickness to chord ratio come from
previous weight sizing and constraint sizing analysis. The incidence angle and dihedral angle of the wing are chosen
to be zero in order to optimize performance and control of the aircraft during high speed flight. Finally, the sweep
41
angle and taper ratio of the wing were chosen based on the F-16 data displayed in Roskam’s Table 6.9 in Part II of
his design series.12
D. Flap Design
Before the full wing can be designed and modeled, the control surfaces that will be placed on the wing must be
sized and located. The first of these control surfaces that must be designed is the flaps on the wing. During takeoff
and landing, the vehicle requires a large cL,max than can be produced by a plain wing. Therefore, flaps are needed to
increase the lift on the vehicle and either help it get in the air on takeoff or help it slow down upon landing. In order
to decide which flaps to use and how to size these flaps, a process was used to determine the change in C l,max that
each flap would produce. First, the change in cL at takeoff and landing was calculated using Eqn. 27. The values of
CL,max for takeoff and landing were taken from the previously assumed values during the constraint analysis.
Table 30: Maximum Lift Coefficients
CL,max,TO CL,max,L
1.8 2.2
ΔC Lmax ¿ /L
=1.05(CLmax¿ / L
−CLmax) (27)
Then, the required increase in cl,max due to the flaps being lowered was calculated using Eqn. 28.
Δcl max=
ΔC Lmax∗S
Swf
K Λ
(28)
The value KΛ accounts for the effect of sweep angle when the flaps are down and can be calculated using Eqn. 29.
K Λ=(1−.08 cos Λ c4
2)cos Λc /43/4
(29)
The ratio of the main wing area to the flap area can be estimated using multiple values between zero and one and
running the calculations multiple times. The necessary increase in c l due to flap deflection can be calculated by Eqn.
30.
Δcl=1K
Δclmax(30)
12 Roskam, Jan. Preliminary Configuration Design and Integration of the Propulsion System. Lawrence, Kan.: DARcorporation, 2004. Print.
42
The factor K can be found for each type of flap using Fig. 7.4 in Roskam’s Part II13. Finally, the increase in cl due to
the flaps can be calculated using Eqn. 31.
Δcl=c l∝∝δ f
δ f (31)
The value of αδ,f is the section lift effectiveness parameter and can be found using Fig. 7.8 in Roskam 14. The δf
represents the flap deflection. For this aircraft, Swf/S of .84 and a flap chord to main wing chord ratio, c f/c, of .30
were chosen. Due to the high change in lift needed, Fowler flaps were chosen to be placed on the wing. The result of
these calculations is shown in Table 30 below.
Table 31: Flap Sizing Values
KΛ Swf/S bf/b K αδ,f δf (°)
Takeoff .74 .4 .75 .92 .53 25
Landing .74 .4 .75 .92 .46 40
The result of these calculations was a Fowler flap covering 75% of the span and 40% of the wing area. The flap
would be deflected 25° at takeoff and 40° at landing.
E. Aileron Design
The other necessary control surface to place on the wing is the ailerons. Unlike the flaps, for this initial design,
the aileron sizing was taken from historical data provided by Roskam for fighter aircraft in Table 8.9b in his Part
II.15 Using the values in this table as a base point, the aileron was chosen to be at the tip of the wing. The size is
shown in the final 2D modeling.
F. Wing Mode
With the flaps and the ailerons designed, the wing was then designed and modeled in three different views. One
half of the wing is shown with the other half being symmetrical with respect to the midline of the aircraft. The three
views of the main wing are shown in Figs. 23, 24, and 25.
13 Roskam, Jan. Preliminary Configuration Design and Integration of the Propulsion System. Lawrence, Kan.: DARcorporation, 2004. Print.
14 Roskam, Jan. Preliminary Configuration Design and Integration of the Propulsion System. Lawrence, Kan.: DARcorporation, 2004. Print.
15 Roskam, Jan. Preliminary Configuration Design and Integration of the Propulsion System. Lawrence, Kan.: DARcorporation, 2004. Print.
43
Figure 23: Main Wing Top View
Figure 24: Main Wing Side View
Figure 25: Main Wing Front View
G. Final Wing Design Summary
The result of this wing analysis and design was a wing of span 30.6 ft, area of 374 ft 2, 45° quarter chord sweep,
with Fowler flaps along 75% of the span and ailerons near the wing tips. Two spars were added into the wing as can
44
be seen in the top view of the wing. The leading edge spar is placed at .5% of the chord while the second spar is
placed just before the control surfaces.16 In many aircraft, fuel is stored in the wings but for this design, all the
mission fuel necessary was placed inside the fuselage. This design choice was made in order to minimize the weight
and thickness of the wing with the goal of maximizing supersonic performance. In the future, this wing may need to
be altered slightly to account for the position and weight of the vehicle’s engines. However, at this time, the wing
meets all requirements and design choices and can be used for a preliminary modeling layout.
X. Tail Design
The final vehicle component that must be designed during this stage is the vehicle’s tail. This part of the vehicle
is critical for its contribution to stability and control, future weight and balance of the vehicle, as well as a lesser
contribution to lift. In the preliminary configuration analysis, a v-tail was chosen for its high velocity performance
and minimal drag.
A. Tail Configuration
The process by which the tail was designed was the volume coefficient method. Assumptions were made about
the moment arm of the horizontal and vertical tail as well as the volume coefficient of the horizontal and vertical tail
in order to determine the area of the tail required. The area of the horizontal and vertical tail can be calculated
separately using Eqns. 32 and 33.
Sh=V h S c
xh
(32)
Sv=V v Sb
xv
(33)
Because the tail is a v-tail, the horizontal and vertical surface areas must then be combined into one surface with a
dihedral angle that can be calculated easily using Eqn. 34.
Γh=tan−1 Sv
Sh
` (34)
The final values from these calculations are shown in Table 31.
Table 32: Volumetric Coefficient Method
x V S dihedral (°)
Horizontal 20 0.3 68.60 38.1
16 Roskam, Jan. Preliminary Configuration Design and Integration of the Propulsion System. Lawrence, Kan.: DARcorporation, 2004. Print.
45
Vertical 20 0.094 53.74 38.1
B. Tail Geometry Specifications
After the surface areas and dihedral angle for the tail have been calculated, the next step in the process was to
choose the geometric parameters which would define the shape of the tail. These parameters include the incidence
angle, the aspect ratio, the sweep angle, the thickness ratio, the airfoil, and the taper ratio. These choices were made
based on the previously designed main wing as well as values taken from Roskam’s Tables 8.13 and 8.14 in Part II. 17The final values chosen for the tail geometry are shown in Table 32.
Table 33: Tail Sizing Values
AR Sweep (°) taper t/c airfoil incidence (°)
3 40 .3 .04 NACA 64-204 0
C. Tail Control Surfaces
Similarly to the design of the main wing, before the tail can be fully designed and modeled, the control surfaces
that will be placed on the tail must be sized and located. Due to the designed tail being a v-tail, the two control
surfaces normally on the horizontal and vertical tail of an airplane, the elevators and the rudder, were combined into
one control surface which controlled both pitch and yaw motion. The basis for the these sizing and locating
decisions was the data provided in Roskam’s Table 8.9a and 8.9b in Part II18. The v-tail control surfaces for this
aircraft were based on the control surfaces of similar style fighter aircraft. By this reasoning, the entire length of the
span of the v-tail was used for the ruddervator. The final control surface design and placement can be seen in the
design model of the tail.
D. Tail Model
With finalized values for the tail and control surface sizing, the final tail can be designed and modeled. Only one
tail is shown in these models with the other tail being a reflection across the center of the aircraft. The three views of
the tails are shown in Figs. 26, 27, and 28.
17 Roskam, Jan. Preliminary Configuration Design and Integration of the Propulsion System. Lawrence, Kan.: DARcorporation, 2004. Print.18 Roskam, Jan. Preliminary Configuration Design and Integration of the Propulsion System. Lawrence, Kan.: DARcorporation, 2004. Print.
46
Figure 26: Tail Top View
Figure 27: Tail Side View
47
Figure 28: Tail Front View
E. Final Tail Design Summary
The result of the tail design process is a v-tail on each side of the midline of the aircraft with a height of 4.31 ft, a
width of 5.50 ft, and a length of 5.86 feet. The ruddervator is located at the back of this v-tail and will be used to
control both pitch and yaw of the vehicle. While this may require a more complicated feedback response controller
and sensors, the v-tail gives much better performance in the conditions required for this mission. This tail will likely
be moved and resized in the weight and balance process but for this preliminary design, the v-tail meets all
requirements and chosen parameters and can be used to model the first stage of the design.
XI. Final Design Summary
Once all three major vehicle components had been sized, designed, and modeled, they could be combined to
create the first working visual model of the full aircraft. This aircraft will need much more analysis and repetitive
iteration through all steps of the design but with this model, the design can proceed into more detailed design work.
F. Final Model
The final model of the preliminary design for the uninhabited long range strike vehicle is shown in Fig. 29.
48
Figure 29: Vehicle Top View
The result of combining the three components designed in this initial design phase is a vehicle that somewhat
resembles a large missile. This is realistic because at the high supersonic speeds this vehicle is designed for, the
vehicle shape needs to be streamlined and narrow to reduce the impact of the wave drag. One important parameter
that must be analyzed with the final configuration is the supersonic or subsonic leading edge of the vehicle. A
supersonic leading edge results in shocks forming on the surface of the wing. In order to greatly reduce the
disturbances across the wing, the leading edge must be contained within the Mach cone that the vehicle creates in
flight. All flow within this cone is initially subsonic so the leading edge of the vehicle wing will interact with
subsonic flow. The relationship to calculate the Mach cone of the vehicle is shown in Eqn. 35.
μ=sin−1 1M
(35)
At Mach 2, this cone is 30° on either side of the line of symmetry of the aircraft. The angle between the nose of
the aircraft and the leading edge of the tip chord is shown in Fig. 30.
49
Figure 30: Vehicle Subsonic Leading Edge
G. Neutral Point
One crucial point on the aircraft to determine from this initial design is the neutral point. The neutral point is the
point on the aircraft which defines the location of the center of gravity which would be statically neutral. The neutral
point is a critical factor in computing the longitudinal static stability of the entire aircraft. The distance between the
center of gravity and the neutral point is called the static margin and is a measure of this stability. If the neutral point
is not behind the center of gravity, then the vehicle is unstable. In order to find the neutral point for this
configuration, the coefficients of lift, coefficients of moment, and other geometric factor were used. The
relationships used to find the neutral point are shown below in Eqns. 36, 37, 38 and 39.
CL ,α , w=C l , α , w
1+Cl , α ,w
π ARw
(36)
CL ,α ,t=Cl , α ,t
1+C l ,α , t
π AR t
(37)
dεdα
=2CL, α ,w
π ARw
(38)
xNP
c=
x AC
c+η V H
cL ,α ,t
cL ,α , w
(1− dεdα
) (39)
50
The values used in these calculations are shown in Table 33. The results of the neutral point calculations are
shown in Table 34.
Table 34: Neutral Point Analysis Values
c xac/c CM,α,f Cl,α,w Cl,α,t η VH ARw ARt
12.2 .25 -.24 6.11 6.11 1 .3 2.5 3
Table 35: Neutral Point Calculations
de/dα cL,α,t cL,α,w XNP/c c XNP
.875 3.71 3.44 .360 12.2 5.54
Using these values, the neutral point of the aircraft is calculated to be 5.54 ft past the leading edge of the main
wing. This means that the center of gravity of the wing must be in front of this point in order for the vehicle to be
stable. The location of the neutral point on the vehicle is shown in Fig. 31 below.
Figure 31: Neutral Point Location
XII. Landing Gear and Weight and Balance
The final step in the preliminary design process is the design and addition of landing gear to the aircraft and
then the process of determining the weights of each component to determine the center of gravity of the vehicle.
51
This step allows for a finalized preliminary design of the vehicle to be completed with basic consideration for
important factors like stability. It is possible, during this process, to determine that the entire designed aircraft is
unfeasible and cannot be fixed without major redesign of one or more of the components.
A. Component Weight Breakdown
The first step in this process was to determine the weights of each of the individual components being placed
into the fuselage. This step is necessary because a weighted center of gravity for each of these components will
produce the center of gravity for the overall aircraft. Weights were calculated for the various systems and then
specific components by using data taken from Roskam’s Part V19. The values chosen for this analysis were taken
from the F-18 Hornet due to its similar style and performance capabilities. The most important value for this
analysis was the flight design gross weight, WG. The ratios used to determine these weights are shown in Table 35
below.
Table 36: Gross Weight Ratios
WTO/WG Wstructure/WG Wpower/WG Wfixed/WG Wwing/WG Wempennage/WG Wfuselage/WG Wengine/WG Wgear/WG
0.623 0.357 0.194 0.158 0.117 0.029 0.145 0.684 0.062
Using these ratios, the weights of each component were calculated. These weights are shown in Table 36 below.
Table 37: Vehicle Component Weights
WG Wstructure Wpower Wfixed Wwing Wempennage Wfuselage Wengine Winduct Wgear
22,887 8,171 4,440 3,616 2,678 664 3,319 3,307 299 1,149
B. Component Center of Gravity
Using these calculated weight values for each component, the individual center of gravity for each component
was calculated based on both its distance from the nose of the aircraft, xcg, and its distance from a reference point
well below the nose of the aircraft, zcg. This reference point was chosen to be 20 feet below the nose of the aircraft
so that with the later addition of the landing gear, the center of gravity location would still be positive. Because the
vehicle is intentionally designed to be perfectly symmetrical, the ycg of the aircraft is known to be 0. Each individual
center of gravity was found using SolidWorks area centroid.
19 Roskam, Jan. Component Weight Estimation. Lawrence, Kan.: DARcorporation, 2003. Print.
52
Table 38: Component Centers of Gravity
Component xcg (ft) zcg (ft)
fuselage 35.3 20.0
wing 46.2 20.0
tail 55.3 24.8
engine 47.0 22.0
air induct 41.0 22.0
fixed equipment 7.0 20.0
fuel 24.0 20.0
payload 40.5 20.0
nose gear 6.0 13.0
main gear 37.7 13.0
The information shown in Table 35, Table 36, and Table 37 includes the landing gear of the aircraft which will
be designed in a later step.
C. Vehicle Center of Gravity
Using the weights and individual centers of gravity for the components of the aircraft, the overall center of
gravity for this configuration can be calculated. There are multiple centers of gravity of interest for this design
process depending on which weights are included in the center of gravity calculation. The five points of interest can
be calculated using Eqns. 40, 41, 42, 43, and 45 as shown below20.
xcgW E
=∑i=1
6
W i x i
W E
(40)
xcgW OE
=∑i=1
8
W i x i
W 0 E
(41)
20 Roskam, Jan. Preliminary Configuration Design and Integration of the Propulsion System. Lawrence, Kan.: DARcorporation, 2004. Print.
53
xcgW ¿
=∑i=1
13
W i x i
W ¿
(42)
xcgW F
=∑i=1
9
W i xi
W OE+W F
(43)
xcgW P
=∑i=1
6
W i x i
W OE+W P
(44)
The resulting centers of gravity from these equations are shown below in Table 38.
Table 39: Vehicle Centers of Gravity
WE (ft) WOE (ft) WTO (ft) WF (ft) WP (ft)
xcg 37.8 37.3 30.7 29.4 38.1
zcg 22.9 22.6 21.0 21.0 22.0
The front-most and aft-most centers of gravity are shown in Fig. 31 below.
Figure 32: Center of Gravity Range
54
D. Weight-C.G. Excursion Diagram
The purpose of calculating all of these different values for the center of gravity was to analyze the potential
movement of the center of gravity during the various flight segments. This is represented graphically using a weight-
c.g. excursion diagram as shown in Fig. 33.
0.4 0.5 0.6 0.710000
15000
20000
25000
30000
35000
40000
We
Payload
Wto
Fuel
Fuel
Woe
Payload
C.G. Location (F.S.)
Wei
ght (
lbs)
Figure 33: Weight-C.G. Excursion Diagram
This diagram shows that the fuel is by far the dominating factor in the determination of the movement of the
center of gravity. This makes sense because in supersonic flight, a large amount of fuel will be burned at a rapid
rate. Initially, the center of gravity will be much further forward. However, as the fuel is burned, the center of
gravity will move backwards. This results in a center of gravity range of 8.7 ft. This is a reasonable value for the
range because of the large changes that occur during sustained supersonic flight. In addition, all of these values are
in front of the previously calculated neutral point position at 38.2 ft behind the nose. This means that the vehicle will
always be statically stable.
E. Landing Gear Configuration
The final component that must be designed for this aircraft is the landing gear. The landing gear must be
designed such that the vehicle is capable of easily taking off and landing safely, the vehicle will not tip over in either
the longitudinal or the lateral direction, and that the gear can be folded up inside the aircraft structure after takeoff.
This is particularly important because in supersonic flight, every exposed piece of the aircraft creates a large amount
of a vehicle with fixed landing gear would create a very large amount of excess, wasteful drag. Therefore, for this
design, the landing gear configuration has been chosen to be a traditional tricycle with retractable gear. This
configuration is the simplest and most commonly used for this style of aircraft.
55
F. Gear Design
When designing the landing gear for this aircraft, four criteria must be met: the gear must prevent the entire
vehicle from touching the ground when the vehicle is landed, the gear must prevent longitudinal tip over, the gear
must prevent lateral tip over, and the gear must retractable into the vehicle structure. Due to the thin nature of the
wings, the main gear may be attached to the lower surface of the wing but the bulk of the gear and the tires must be
stored inside the fuselage.
In order to prevent the vehicle from touching the ground at any time, the center of the tires have been placed 7
feet below the nose of the aircraft. This ensures that the vehicle will not hit the ground at any point while it is on the
ground. One strut and one tire have been chosen for the nose landing gear because this vehicle is relatively light and
does not need a large amount of reinforced landing gear. The location of the nose landing gear has been chosen to be
6 feet behind the nose of the aircraft. This is done because the nose landing gear is located very near to the nose of
the aircraft and in this location, the vehicle can be retracted backwards into the fuselage. In the fuselage, they will be
retracted beneath the fixed equipment placed near the front of the aircraft. The nose landing gear tires have a
diameter of 2 feet and can easily be placed in the structure as can be seen in the fuselage side view in Fig. 17.
The main landing gear have been placed 39.9 feet behind the nose of the wing. The height of the gear is the
same as the nose gear and the distance behind the nose is determined by a 15 degree angle between the landing gear
and the most aft center of gravity. The gear is attached on the wing at 8.5 feet on either side of the axis of symmetry.
This location is determined by a 50 degree angle that is determined by the line between the nose and main gear,
passing through the front most center of gravity and ending at the opposite side main gear. The main gear of the
aircraft is designed to be retracted laterally into the fuselage on either side of the payload at the rear of the aircraft.
Sufficient space for these landing gear can be seen in the top view of the fuselage in Fig. 16. Similarly to the nose
gear, the main gear at the rear of the aircraft have been chosen to have on strut and one tire. The final configuration
and implementation of the landing gear is shown below in Fig. 34.
Figure 34: Landing Gear Side View
G. Landing Gear Loads
56
In the design of the landing gear, it is important to calculate the loads that the landing gear will be placed under.
This load analysis can help determine the number of tires, the tire size, the number of struts, and the materials
chosen for the manufacturing. The load on the nose wheel strut and main gear strut are calculated according to Eqns.
45 and 46 respectively.
Pn=W ¿ lm
lm+ln
(45)
Pm=W ¿ lm
ns(l¿¿m+ ln)¿ (46)
The value of ln is defined as the distance between the nose gear and the center of gravity and the value of l m is
defined as the distance between the center of gravity and the main gear. The value of n s is chosen to be 1 for both
sets of gear. The values used for these calculations and the results are shown in Table 39 below.
Table 40: Gear Strut Load Values
WTO (lbs) ln (ft) lm (ft) ns Pn (lbs) Pm (lbs)
36,711 32.1 1.9 1 2,031 34,679
In order to size the tires of the landing gear, two ratios of Pn/WTO and nsPm/WTo are used. Using the calculated
values, these ratios are found to be .055 and .944 respectively. Using Table 9.2 in Roskam Part II 21, these ratios are
then used to size the main gear to be 24x8 inches with a pressure of 210 psi and the nose gear to be 18x6.5 inches
with a pressure of 120 psi. This results in a volume of 2.09 ft3 for the main gear and .96 ft3 for the nose gear.
XIII. Conclusion
The result of this analysis was to produce a preliminary model of a vehicle with a fuselage, a wing with flaps and
ailerons, simple engines, and a v-tail with ruddervators. In the future of this design, more detailed design
considerations like the wing tips, material selection, and internal structure may be added to create a more complete
airplane. The purpose of this RFP was to create an uninhabited, long range strike vehicle capable of executing a
strike mission and returning back to base. This design went through the process detailed in Roskam’s design book
series to create this vehicle one component at a time and eventually combine all of these components together into a
full aircraft model. All of these individually designed components and choices work together in order to create a
vehicle capable of carrying out the design mission in the most effective and efficient manner. The final three views
of the design for this RFP are shown below in Figs. 35, 36 and 37.
21 Roskam, Jan. Preliminary Configuration Design and Integration of the Propulsion System. Lawrence, Kan.: DARcorporation, 2004. Print.
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Figure 35: Final Design Top View
Figure 36: Final Design Side View
Figure 37: Final Design Front View
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In the models shown above, the vehicle is assumed to be in flight and the landing gear in the retracted position.
The design process requires large numbers of iteration and a large amount of very detailed analysis and this is only
the first step. One major consideration in any design that was not considered for this analysis was the cost of the
vehicle. This is always one of the most important things to consider throughout the entire design process. While with
enough time and resources, an aircraft with truly superior qualities might be developed and manufactured, the cost to
the company would be so high that the vehicle would never be produced. However, for the purposes of preliminary
design, cost is not an important factor for this considered RFP and the finalized vehicle has been created for the
purposes of future detailed design.
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References
1. Hunter, Jamie. Jane's All the World's Aircraft: In Service: 2012-2013. Coulsdon: IHS Jane's, 2012. Print.
2. Jackson, Paul A. Jane's All the World's Aircraft: Development & Production: 2012-2013. Coulsdon: IHS Jane's, 2012. Print.
3. "Joint Direct Attack Munition (JDAM) GBU-29, GBU-30, GBU-31, GBU-32."Joint Direct Attack Munition (JDAM) GBU-31. N.p., n.d. Web. 6 Nov. 2014. http://fas.org/man/dod-101/sys/smart/jdam.htm.
4. Raymer, Daniel P. Aircraft Design: A Conceptual Approach. Reston, VA: American Institute of Aeronautics and Astronautics, 1999. Print.
5. Roskam, Jan. Component Weight Estimation. Lawrence, Kan.: DARcorporation, 2003. Print.
6. Roskam, Jan. Layout of Landing Gear and Systems. Lawrence, Kan.: DARcorporation, 2010. Print.
7. Roskam, Jan. Preliminary Configuration Design and Integration of the Propulsion System. Lawrence, Kan.: DARcorporation, 2004. Print.
8. Roskam, Jan. Preliminary Sizing of Airplanes. Lawrence: DARcorporation, 2005. Print.
9. Schmigital, Joel, and Jill Tebbe. JP-8 and Other Military Fuels. Rep. N.p., 12 Jan. 2011. Web. 8 Nov. 2014. www.dtic.mil%2Fcgi-bin%2FGetTRDoc%3FAD%3DADA554221.
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