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1 Introduction
The conceptual design phase is characterised by the

evaluation of many disparate concepts. Evaluation of these
concepts requires the application of a combination of em-
pirical, experimental and computational tools to predict the
concept performance against requirements. However, this
early design stage is also characterised by significant cost and
time constraints. A significant level of risk must therefore be
assumed because of insufficient time or financial resources to
evaluate all the concepts comprehensively. In the case of
configuration development for UCAVs there exists no em-
pirical database and limited experience for the predicting of
their aerodynamic characteristics. This is true not just because
they are a recent concept in military aviation but also because
other requirements, most prevalently low observability, are
forcing extremely novel configurations. This tendency
towards novel configuration solutions is also evident in the
wide range of configurations emerging in the UAV field. The
relevance of existing empirical tools and databases based on
vastly different configurations is thus questionable.

It is argued in this paper that a quasi-physical modelling
process is required to be able to truly capture the per-
formance of the radically differing concepts typical of
UCAVs. This approach attempts to combine the advan-
tages of empirical, computational and experimental tools
to enable the design team to better predict vehicle aero-
dynamic characteristics early in the design process with
increased confidence, and hence to reduce risks.

2 Background
The interest in UCAVs has been driven by a number of

factors, primarily the political necessity to minimise pilot
casualties and to minimise cost at all levels. Principal amongst
these is the drive for affordable weapon systems. It has
been proposed, see for example [1], that UCAVs will lower
acquisition, training and operational costs. Goals established
in US programs in this area are for vehicle acquisition costs

in the order of one-third the cost of the upcoming Joint
Strike Fighter and have 50–80% lower life cycle costs.
These ambitious goals will be achieved through a number of
means. Amongst these will be weight reduction (weight re-
mains an important parameter in vehicle costs) gained from
removing the pilot and associated equipment (such as cockpit
heating, ejection seat and so forth) and training for the
mission operators that can be conducted almost entirely in
simulation (the vehicle need only fly on operational missions,
hence eliminating fatigue and associated flight time driven
cost drivers). The operational cost for a military operation
would be minimised through maximising the platform sur-
vivability. It is this factor, and the demand for low
observability – together with the freedom that accrues from
removing the pilot from the vehicle – that has led to a large
number of innovative, unconventional platforms. One
example of this is the Saab SHARC concept, shown in Fig. 1.

While there are undoubtedly many issues to be resolved
with UCAVs regarding the level of autonomy, systems design,
certification and interoperability with manned platforms,
there also exist questions as to the aerodynamic performance
of such vehicles. Advances in flight control certainly allow for
a wide variation in vehicle design that would not otherwise be
possible. However, the fundamental requirement still exists

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Acta Polytechnica Vol. 41  No. 4 – 5/2001

Rapid Prediction of Configuration
Aerodynamics in the Conceptual

Design Phase
C. Munro, P. Krus

Conceptual aircraft design is characterised by the requirement to analyse a large number of configurations rapidly and cost effectively. For
unusual configurations such as those typified by unmanned combat air vehicles (UC AVs) adequately predicting their aerodynamic
characteristics through existing empirical methods is fraught with uncertainty. By utilising rapid and low cost experimental tools such as the
water tunnel and subscale flight testing it is proposed that the required aerodynamic characteristics can rapidly be acquired with sufficient
fidelity for the conceptual design phase. Furthermore, the initial design predictions can to some extent be validated using flight-derived
aerodynamic data from subscale flight testing.

Keywords: aircraft design, UAV, water tunnel, flight testing.

Fig. 1: Saab SHARC unmanned combat air vehicle concept
(image courtesy Saab AB)



that the configuration must provide sufficient lift with low
drag and the control surfaces be able to respond to de-
mands to manoeuvre and ensure controllability. These
aerodynamically derived characteristics are however rarely in
concordance with low observability requirements.

The focus of the work described in this paper is to enable
the aerodynamic design team to identify critical aerodynamic
(primarily as related to control and stability) issues, predict
performance and perform trade studies to determine the
aerodynamic influence of changes (be they either to the
external aerodynamics or to the control system). It should be
recognised that there is very strong coupling in the case of
UCAVs between the aerodynamics, stability and flight control
functions and hence a need to be able to evaluate the in-
teractions between the three early in the design process.

From a conceptual design standpoint, these requirements
to meet both target performance and cost requirements
place significant pressure on the initial analysis procedures.
Furthermore, much of the cost (particularly that component
driven by vehicle weight) is determined very early on, as
illustrated in Fig. 2. Hence, there is significant leveraging and
longer term payback that can be gained from investing earlier
in conceptual design studies.

The level of modelling fidelity is lower at the conceptual
design stage out of necessity. There must therefore be an

acceptable level of fidelity that is required to enable concept
selection to be undertaken and the requirement definition to
be refined. The methods presented in this paper attempt to
address these combined requirements of low cost and time
while achieving an acceptable level of fidelity for conceptual
design prediction.

3 Design analysis toolbox
The use of computational tools for the prediction of flight

vehicle performance is rightly assuming a great deal of im-
portance in current aeronautical research. The benefits of
such tools are clear: significantly reduced cost and time can, at
least in principle, be achieved and often a greater insight into
the underlying physics and multidisciplinary aspects can be
obtained through the ability to exactly control test parameters
which may well be coupled in the physical system.

In the field of flight performance the use of nonlinear six
degree of freedom flight dynamics models is very well es-
tablished as critical to every stage of vehicle development
from initial system definition and design right through to
training of aircrew. While the mathematical description of
flight dynamics models is relatively simple and readily im-
plementable in computer models, the same cannot be said
for the underlying aerodynamics models. The complexity of
fluids modelling means that computational fluid dynamics
(CFD) is a relatively immature field that has not yet reached
the point of acceptability in aircraft company conceptual
design offices. The reasoning is generally that the cycle time is
too long when there are so many configurations to be studied
(and so many test points to run) and, often, a lack of con-
fidence in the results.

To address this weakness in aerodynamic modelling at
the conceptual design stage a method of building up the
aerodynamic database using rapid experimental and
computational tools around the central flight dynamics mo-
del is proposed, as shown in Fig. 3.

The role of the aerodynamic prediction methods
presented is twofold: validation of simulation results and as
a complement to elements of the digital simulation. From a set
of designs sketched by the conceptual design team (with a
large input from low observability elements as regards the

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Acta Polytechnica Vol. 41  No. 4 – 5/2001

Fig. 2: Influence of design stage on costs and the ability to in-
fluence the design

Fig. 3: Conceptual design process with physical and virtual modelling elements



external configuration) a few may be selected on the basis of
initial empirical analysis to proceed to more detailed model-
ling and experimental investigation. Such activities may
proceed in parallel. Modelling will consist of initial comput-
ational analysis complemented by water tunnel quantitative
data. This water tunnel data may be used to aid in generating
the preliminary aerodynamic database that can be used as
an input to the flight dynamics simulation model that can
be used for initial operational/developmental evaluation.
Furthermore, the flow visualisation capabilities of the water
tunnel provide an insight into the aerodynamic behaviour
and hence guide the design team to potential areas of im-
provement through a greater understanding of the dominant
flow physics that this provides.

The terms verification and validation used here conform
to the test and evaluation community definitions, as detailed
in [2]. Verification need only be performed on major code
changes, to ensure software robustness. Validation on
the other hand is the confirmation of simulation results
with experimental or other means. In this instance,
the validation can be provided by the subscale flight test
elements, providing an independent check of the modelling
and simulation elements that are themselves a combination
of experimental (water tunnel), empirical and digital simul-
ation. The modelling can be adjusted on the basis of the
validation to improve the prediction capability. The design
team can thus have more confidence in the analysis results
when it comes to evaluating these results against design
requirements. This in turn increases the confidence in the
design, helps identify key problem areas requiring further
work and reduces the risk. Conversely, this reduced risk could
be turned to allow more radical configurations to be evaluat-
ed with the same level of risk as without this approach.

Key elements of this design process are two relatively novel
experimental tools: the water tunnel and subscale flight
testing. It is the contention of this research that these methods
both have significant potential in the conceptual design phase
for UCAV aerodynamics, although their limitations
are significant and must be recognised.

4 Novel experimental tools
While experimentation is undoubtedly a rather expensive

and time consuming activity in comparison to simulation, the
development of modern, cost effective and accurate instru-
mentation has driven down experimental costs and cycle
time. Furthermore, questions remain in the conceptual
design area over the feasibility in the near-term of utilising
complex, long cycle time simulations. The water tunnel and
subscale flight test tools that are introduced here are good
examples of this trend. Both tools have their advantages and
disadvantages in terms of time, cost and modelling fidelity,
and these are introduced in this section.

5 Water tunnel
The water tunnel has long been used as a diagnostics tool

for external flows (see for example [3] and [4]). For UCAVs,
the demand for low observability tends to chined fuselage
geometries and swept, relatively sharp wing leading edges.
The flow over such geometries at moderate to high angles of

attack will in general be dominated by vortical flow with fixed
separation lines along the sharp wing leading edges and
fuselage chines. This geometrically fixed separation combin-
ed with the vortex dominated separated flowfield makes such
flows Reynolds insensitive ([5] and [6] are typical examples
illustrating the Reynolds number insensitivity of such flows)
and hence amenable to analysis in low Reynolds number
facilities such as water tunnels.

While flow visualisation has been well demonstrated in
water tunnels, the use of strain gauge balances to allow force
and moment measurement is relatively new ([7], [8]). Initial
test results performed as part of this work on generic delta
wing models indicates excellent correlation of both lift curve
slope and maximum lift coefficient with wind tunnel data, as
shown in Fig. 4. Note that the Reynolds number as listed here
is based on root chord and that the lift coefficient value does
not account for the contribution of tangential force. Hence,
the true lift coefficient is slightly lower at high angles of
attack than shown here. Nonetheless, this result indicates the
high level of accuracy that can be rapidly achieved while
remaining within the time and cost constraints imposed at the
conceptual design stage.

6 Subscale flight testing
The use of subscale flying models for free dynamics test-

ing has become increasingly possible in recent years due
to the development of lightweight, low power instrumenta-
tion and telemetry systems. Examples of projects that have
been undertaken in this area include the Boeing/NASA
X-36 fighter 28% scale demonstrator [9], NASA experi-
mental hypersonic configuration [10] and the Saab T28
instrumented model (see Fig. 5).

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Acta Polytechnica Vol. 41  No. 4 – 5/2001

Fig. 4: Matching of force data for water and wind tunnel tests of
a 65° delta wing



Subscale flight testing offers the benefit over ground-
-based tests of being fully six degrees of freedom, enabling re-
alistic manoeuvres to be performed (although inertial scaling
remains an issue requiring solution). Particularly for high risk
tests such as at high angle of attack and departures such as
spin, the subscale demonstrator offers the opportunity to ex-
plore these corners of the flight envelope in a safer manner
than with a fullscale vehicle and at much lower cost. Further-
more, the subscale model can be built early in the design pro-
cess (perhaps late in the conceptual phase) whereas the
fullscale demonstrator can only be tested after design work is
essentially complete. Particularly for UCAVs, these can readily
demonstrate technologies key to unmanned operation in ad-
dition to exploring a configuration’s aerodynamic
performance.

Advances in parameter identification methods combined
with the widespread availability of fast computers have
enabled the rapid identification of aerodynamic parameters
from flight test data. The resulting set of aerodynamic
and control derivatives can then readily be compared to
simulation results for validation and improvement of these
prediction approaches. Furthermore, the possibility exists to
perform tests rapidly with variations of platform geometry to
assess alternative configurations and perform trade studies.

Initial testing has been performed to confirm that a
complete set of inertial and air data can be readily record-
ed onboard and telemetered to the ground in real time for
a payload weight of under 5 kg and at very low cost. Work
is currently underway on a small UCAV-type vehicle for
demonstration of the concept in a more realistic con-
figuration. Further, the work will be validated against
fullscale flight test and wind tunnel data on a number of
representative configurations.

7 Methods integration
The two methods described in this paper are incorporated

into the design process as shown in Fig. 3. As shown in Fig. 6,
the two novel methods proposed here fit into a spectrum of
experimental tools that can be utilised in the design process.
Through careful selection of these methods with an
underlying simulation capability that develops as the aircraft
develops, the potential exists for more rapid and effective
aerodynamic prediction. Note also how the tendency is for

the last 10 % of accuracy to cost much more than for the
initial, conceptual design level estimate.

Neither water tunnel testing or subscale flight testing can
replace the wind tunnel or fullscale flight testing in de-
veloping an aircraft to certification. However, at the very early
design stages where there are a large number of options to be
studied and time and financial resources are limited, these
tools offer some potential to reduce risk and increase the
design knowledge. This in turn, has a great leveraging effect
on the overall development cost, as was indicated in Fig. 2.

8 Conclusion
The aerodynamic conceptual design of novel configura-

tions such as UCAVs present significant problems to the aero-
dynamic designer, who is dependent on empirical (hand-
book) approaches combined with time consuming and costly
wind tunnel and CFD analysis. It is proposed in the present
research that useful additions to the design team’s analysis
toolbox may be the water tunnel and subscale flight testing.
These two experimental methods fit into a simulation frame-
work by enabling validation of simulation results and by com-
plimenting flight dynamics modelling by reducing the need for
more costly aerodynamic prediction methods early in the de-
sign process.

Further work is currently underway to validate both the
water tunnel and subscale flight testing against baseline test
configurations for which there are readily available wind
tunnel and fullscale flight test data. Work is also underway to
address the dynamic scaling issues relevant to subscale flight
testing and how they can be addressed.

Acknowledgments
The first author’s work in this area is supported by

the Swedish Engineering, Design, Research and Education
Agenda (ENDREA). The authors also wish to acknowledge
the support of Saab AB in conducting this work.

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Acta Polytechnica Vol. 41  No. 4 – 5/2001

Fig. 5: T28 Trojan instrumented model aircraft

Fig. 6: Tradeoffs of accuracy and cost in methods selection



References
[1] DARPA System Capability Document – Unmanned Combat

Air Vehicle Operational System. http://www.darpa.mil/tto/
downloadables/UCAV/APPENDIX.doc, 1998

[2] Hall, D. H., Kilikauskas, M., Laack, D. K., Muessig, P. R.,
O’Neal, B., Richardson, C., Simecka, K., Stewart, W.,
Turner, S. W.: How to VV&A without really trying.US Joint
Accreditation Support Activity JTCG/AS-97-M-00 9,
1997

[3] Del Frate, J. H.: NASA Dryden Flow Visualization Facility.
NASA TM-4631, 1995

[4] Malcolm, G. N., Nelson, R. C.: Comparison of Water and
Wind Tunnel Flow Visualization Results on a Generic Fighter
Configuration at High Angles of Attack. AIAA 87-2423,
1987

[5] Erickson, G.: Vortex Flow Correlation. AFWAL-TR-80-
-3142, 1981

[6] Roos, F. W., Kegelman, J. T.: An Experimental Investiga-
tion of Sweep-Angle Influence on Delta-Wing Flows. AIAA
90-0383, 1990

[7] Suarez, C. J., Malcolm, G. N.: Water Tunnel Force and
Moment Measurements on an F/A-18. AIAA 94-1802, 1994

[8] Cunningham, Jr., A. M., Bushlow, T., Mercer, J. R., Wil-
son, T. A., Schwoerke, S. N.: Small Scale Model Tests in
Small Wind and Water Tunnels at High Incidence and Pitch
Rates. AD-A208647, Vol. 1–3, 1989

[9] Walker, L. A.: Flight Testing the X-36 – The Test Pilot’s Per-
spective. NASA CR-198058, 1997

[10] Budd, G. D., Gilman, R. L., Eichstedt, D.: Operational
and Research Aspects of a Radio-Controlled Model Flight Test
Program. Journal of Aircraft, 32, 1995, pp. 583–589

Cameron Munro, BEng(Aero), BBus
phone: +46 13 285783
fax: +46 13 130414
e-mail: cammu@ikp.liu.se

Petter Krus, Ph.D.
phone: +46 13 281792
fax: +46 13 130414
e-mail: petkr@ikp.liu.se

Department of Mechanical Engineering
Linköpings Universitet
581 83 Linköping, Sweden

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Acta Polytechnica Vol. 41  No. 4 – 5/2001