AP01_45.vp


1 Introduction
The engineering design process of a new aircraft starts

with a set of requirements which are to be met by one or
several aircraft concepts that we may call solutions, being
developed along the timeline. During the conceptual design
phase, on which this paper is focused, various possible
solutions are investigated, modified, abandoned or further
developed. Simultaneously, several requirements may face
a discussion, in which the required parameter values, and
even the requirements themselves, are questioned and
changed if necessary. Later, the preliminary design phase will
follow, looking further into only a few particularly promising
aircraft studies, the number of which will be reduced to
a single concept to enter the detailed design phase. By then,
the requirements will be far more rigid than during the
conceptual design stage.

The design phases are characterised by steadily chang-
ing degrees of knowledge, freedom of design, and cost of
change (Figure 1). Knowledge is information about the evolv-
ing aircraft project. Naturally, in the early design phase, it is
incomplete or imprecise, so assumptions are often made.
These assumptions, if incorrect, can lead to poor decisions
that precipitate project failure, budget and/or schedule over-
runs, etc. Freedom of design is a measure of flexibility, or the
degree to which changes in the aircraft characteristics are
realistic. Cost of change refers to the resource allocation which is
determined by the decision-making processes.

Key decisions made early in the design process determine
a comparatively large number of aircraft parameters as well as
a high percentage of the total cost committed, as [1] points
out. Unfortunately, these decisions are often based on mini-
mal knowledge and incomplete or inaccurate information.
Necessary revisions in later design phases are significantly
more expensive and complicated than are changes early in
the process. So there is a desire to shift knowledge forward in
the design timeline, enabling better substantiated decisions.
This faster increase of design knowledge implies changes of
improvement in the conceptual design stage, as these better
substantiated decisions then meet a more flexible and less

costly-to-change aircraft design state (as indicated by the
arrows in Figure 1).

In order to accomplish this, a tool is required to help
increase and improve the information about the evolving
aircraft project in the early design stages, allowing a sounder
review of presented solutions and of the design driving re-
quirements. One possible approach is an iterative scaling
process, which will be described in detail below. Here, starting
from a model reference aircraft not yet meeting all require-
ments, several parameters are resized – scaled – deliberately
in each step, thus describing a scaled aircraft with new charac-
teristics, which, in turn, are subject to investigation. This
iteration is guided by the objective of an aircraft design which
optimally satisfies the initial requirements with respect to
a selectable figure of merit, e.g. total mass. At the same time,
various design sensitivities become apparent along the itera-
tion, adding to the desired information base.

At the Chair of Aeronautical Engineering of the Tech-
nische Universität München, the FASTR ( Flexible Aircraft
Scaling To Requirements) program is currently being devel-
oped as a modern computer-aided approach to run this
scaling process automatically, as will be described in detail

©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/ 93

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

Cargo Aircraft Conceptual Design
Optimisation Using a Flexible

Computer-Based Scaling Approach
F. Schieck, D. Schmitt

In the early design stages of a new aircraft, there is a strong need to broaden the knowledge base of the evolving aircraft project, allowing a
profound analysis of the solution concepts and of the design driving requirements. The methodology presented in this paper provides a tool
for increasing and improving in an exemplary manner the necessary information on cargo aircraft. By exchanging or adapting a few
particular modules of the entire program system, the tool is applicable to a range scale of different aircraft types. In an extended requirement
model, performance requirements are represented along with other operational requirements. An aircraft model is introduced in sufficient
detail for conceptual design considerations. The computer-aided scaling methodology is explained, which, controlled by an optimisation
module, automatically resizes the aircraft model until it optimally satisfies the requirements in terms of a selectable figure of merit. Typical
results obtained at the end of the scaling are discussed together with knowledge gained during the process, and an example is given.

Keywords: aircraft conceptual design, aircraft scaling, mass growth factor, aircraft multidisciplinary design optimisation.

Fig. 1: Changes of chances during the conceptual design phase



in the following sections. In this context, aircraft require-
ments, which can be integrated into a requirement model, are
introduced as design objectives in Section 2. Complementing
the requirement model, an aircraft model is presented in
a sufficient grade of detail for conceptual design consider-
ations in Section 3. Subsequently, the FASTR core, an
automated scaling algorithm, is described in Section 4. The
results of this scaling process are discussed in Section 5, and
an example is given in Section 6.

2 Aircraft requirements as design
objectives
The engineering design process of a new aircraft begins

with the specification, that has to be reached in the end with
a certain technical solution. Hence, during all scaling efforts,
the specification defines the design-guiding boundary condi-
tions. A full specification consists of several requirements,
most of them relating to performance. With few exceptions,
e.g. a dedicated stealth aircraft, where stealthiness and low
signatures may dominate the whole design [2], performance
requirements can be considered strong design drivers in an
aircraft project. The approach described herein will therefore
set one focus on performance requirements, as will become
apparent in Section 4.

These demanded performances can be divided basically
into point performance requirements (Table 1) and mission perfor-
mance requirements (Table 2). The former describe singular
performance items which have to be satisfied at a single point
in time with a fixed aircraft setup. The latter relate to perfor-
mance requirements which have to be met in a mission con-
text, along a flight profile, with e.g. a steadily changing fuel
mass. For both requirement classes, various formula systems
have been developed and have been published [3], [4].

However, an aircraft specification is not restricted to per-
formance requirements alone. Several operational require-
ments must be met as well (Table 3). In the given example,
a dedicated cargo aircraft is characterised; aircraft with other
main purposes like e.g. an unmanned reconnaissance vehi-
cle can possibly be categorised by other operational
requirements.

Most of these operational requirements are not immedi-
ately reflected in the above formula systems and performance
models. The proposed scaling approach therefore includes an
extended requirement model, enabling automated expansion
of the above operational requirements into technical
solutions with quantifiable effects on mass and drag, as well as
further technical boundary conditions. These requirements
are thus made compatible with the FASTR core formula
system, which mostly relies on the above mentioned formulas
and equations. A specified in flight refuelling capability, e.g.,
will be translated into the integration of a specific subsystem,
a refuelling probe, with defined individual mass and drag
properties. Other requirements will lead to the introduction
of several restrictions in the aircraft’s overall configuration.
With this, an extensive requirement model as a guide for the
scaling has been defined.

3 Aircraft model
For conceptual design considerations, an aircraft can be

described by a set of variables, following a model in a suffi-
cient grade of detail. In the FASTR approach, some 250
variables are currently used, describing a certain aircraft setup
in the first part in terms of geometric key figures, furthermore
propulsion, aerodynamic, and mass properties.

Necessarily, this variable model is complemented in a sec-
ond part by several methods (see below) for parameter value
determination of the variables of the first part. In this way,
e.g. a certain wing area can be methodically associated with
a certain mass and certain aerodynamic characteristics, and
a resize of the former automatically yields changes in both
latter variables.

In this methods-part, the “rubberised” propulsion device
is calculated according to a generic engine model [5]. The
prediction of a longitudinal aerodynamic dataset, includ-
ing trim losses, relies on handbook methods [6], [7], [8]. Mass
determination also relies on handbook methods [9], [10].
Additionally, the methods-part includes an automated rule-
-making functionality around a freely definable design point,
e.g. a referenced baseline aircraft as described in Section 4,
enabling even better model accuracy in parameter variations
closely around that well-defined reference. The methods-part
is designed to be exchangeable for different types of aircraft.

For the developing and validation phase of the FASTR
approach, a conventional cargo aircraft configuration with

94 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

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

Point performance requirements
At any given fuel and payload percentage

– Stall speed – Sustainable load factor

– Take-off run length – Specific excess power

– Turn rate – Landing run length

Table 1: Point performance requirements

Mission performance requirements

– Payload mass – Climb rate
In a
mission
context

– Range – Acceleration

– Cruise altitude – Manoeuvres

– Cruise speed – Store drop

Table 2: Mission performance requirements

Operational requirements

– Quick re-role capability (cargo transport – passenger
transport – medevac aircraft)

– Pressurised cargo compartment

– Rapid centre of gravity shift capability

– In flight refuelling capability

– Quick cargo handling roll-on roll-off capability

– Ground operations on unprepared strips and without
ground handling means

– Survivability (military applications)

Table 3: Operational requirements



a high wing is modelled. Since this model is exchangeable,
however, it does not basically restrict the proposed scaling
algorithm described in the following.

4 Automatic scaling algorithm
The described aircraft model is sized in the scaling

process, as a whole or in part, in order to meet certain speci-
fied requirements – e.g. by increasing the tank volume, thus
enabling a specified better mission range.

At the beginning of this proposed automated scaling
process, a number of ground rules for the scaling, e.g. parame-
ter value minimum/maximum envelopes, a master mission
profile (see below), key figures like wing loading to be kept
constant, or scaling boundary conditions used by the optimi-
sation module (see below) can be set individually. Further-
more, in another pre-processing step, the process continues
with the mentioned automated expansion of operational re-
quirements (Table 3) into boundary conditions to be reflected
during the scaling.

The sizing then starts from a certain baseline aircraft ac-
cording to the aircraft model described in Section 3. This
baseline design represents an in-itself consistent reference
aircraft dataset and a metric for further investigation of scal-
ing results. The baseline design, however, does not need to
meet the required performance, and does not necessarily
represent an optimum design with respect to any objective.

During the iterative scaling process, the current aircraft
dataset is analysed in several modules in order to ascertain
whether the given requirements can be satisfied, whether the
current aircraft is over-designed, or whether it still lacks
potential (Figure 2). This investigation focuses primarily on
performance requirements. First, several required point per-
formances listed in the aircraft specification are investigated
(Table 1): here the performance figures of the current aircraft
dataset are computed and checked against the requirements.
If the current aircraft dataset over-qualifies or fails by a de-
finable margin in this comparison, the responsible aircraft
parameters are correspondingly marked for change.

In the next module, required mission performances are
investigated as well (Table 2). The FASTR approach allows the

flexible definition of a master mission profile with a modular
construction system. Single mission segments, each defined
separately, can be combined without any restriction, generat-
ing a mission which the current aircraft dataset “flies along” in
any desired time resolution (Figure 3).

Moreover, a stability and control module is run to ensure
certain aircraft handling qualities according to the require-
ments.

Finally, the compliance of the overall design with geomet-
ric restrictions, e.g. to prevent the blades of an upscaled pro-
peller from touching the ground, is tested in a separate
module.

At the end of this downloop a rescale decision is met: if the
current aircraft design satisfies all required criteria investi-
gated earlier, the algorithm terminates with a “tailor-made”
solution to fit the specification. If, on the other hand, there is
still a need for scaling, and the parameters in question are still
within their value envelopes, a parameter resize is initiated.

A loop-back then allows scaling of the current aircraft
design in terms of engine size, wing, empennage, and fuse-
lage dimensions as well as fuel mass corresponding to tank
volume. Currently, about 25 variables used in the aircraft
model are subject to direct manipulation – e.g. wing area. The
ground rules contain an initially definable list of parameters
subject to change during the scaling, so that scaling inves-
tigations under specific restrictions, e.g. a resize of wing
properties only, are possible. Along the design loop, associ-
ated changes in the other variables describing the propulsion
device, aerodynamics and masses, which are indirectly
triggered by that direct rescaling, are determined according
to the methods-part of the aircraft model (Section 3).

This iterative process automatically resizes the baseline
design towards the “tailor-made” design, aiming at the fa-
voured minimum-mass solution. To decrease the run-time,
the rescale algorithm relies on a Newton-solver, enabling
quick detection of the wanted solution in only a few itera-
tions. This scaled design is represented by a list of aircraft
properties according to the used aircraft model, regarding
geometry, propulsion, aerodynamics with drag as the domi-
nating parameter, and mass. Calculated point performance
data, mission performance results, and stability/control prop-
erties complete the representation.

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

Fig. 2: Proposed scaling algorithm (simplified)

Fig. 3: Flexible mission model (supply mission example)



A simple optimisation module finally evaluates the result-
ing scaled design regarding a selectable figure of merit, e.g.
aircraft total mass, and decides on a new scaling run with
slightly changed scale criteria. Thereby, several technical
variants for solving same problem are investigated – e.g.
a required high climb rate, which could be achieved with the
help of either a huge wing, or a powerful propulsion device,
or a sophisticated high-lift system, or a combination of all of
these – and the best solution concerning this figure of merit is
isolated.

At present, both aircraft model and requirement model
refer to a dedicated cargo aircraft. The presented scaling
methodology, however, is not restricted to this aircraft type.
The same methodology is currently being used in a joint
Academia-Industry research project for a scaling tool applica-
ble for UAV conceptual design and scaling [11].

Running on a modern standard personal computer,
a FASTR run typically takes less than a minute. It should be
noted, however, that the described scaling method does not
necessarily converge. In this case, the parameter value of one
or several requirements prevents the algorithm from reaching
a realisable aircraft; relying on an iteration counter, the algo-
rithm will nevertheless terminate. Since the scaling log file
will in any case display the then futile efforts to achieve the ob-
jectives, the FASTR approach also functions as a quick test for
the feasibility of the requirements against the background of
the baseline design. So in any case the FASTR approach yields
results, which will be discussed in the following.

5 Results of the scaling process
With a number of optimisation module-controlled scaling

processes, various scaled designs are available – each match-
ing the requirements, but differing along a parameter list
according to the individual ground rule-setting. Every single
solution can be plotted in various diagrams, e.g. in a common
design diagram showing power loading versus wing loading
(Figure 4). Since each plotted point represents a complete
design, several trends are determined, e.g. as defined by the
aircraft total mass as a rough figure of merit, and the single so-
lutions are evaluated individually. As additional guidelines,
various boundaries are mapped which result from individual

requirements: in the shaded areas those combinations of the
variables are located which fail to satisfy certain requirements.

The data obtained implicates even more than a variety of
solutions that can be visualized in the diagram below. For ex-
ample, mass growth factors – i.e. values for the partial dif-
ferentiations of the aircraft total mass relative to a certain
required aircraft quality [12] – are available through dedi-
cated FASTR runs. Thus the sensitivity of the baseline design
concerning a certain requirement becomes apparent in terms
of a total mass change. Specifically, this requirement may be
any point performance requirement (see Table 1), or mission
performance requirement (see Table 2), or additional opera-
tional requirement (see Table 3). Aircraft total mass as a figure
of merit is currently used because of its implications, as there
are methods available to easily derive rough cost and time
schedule estimations from mass data [13]. Another parame-
ter, e.g. aircraft total drag, could be investigated as well. With
these results, the penalties – in terms of additional mass or
drag – which have to be accepted in order to satisfy a certain
requirement become clearly evident. So it is possible to make
a critical review of the basic set of requirements, maybe
slightly weakening the one or other desired parameter value,
while focusing on a better overall performance in the end
with respect to a definable figure of merit.

Moreover, as the FASTR algorithm with its optimisation
module can be used to investigate several technical options
for meeting the same requirement, a discussion of favoured
basic technical approaches can be provided as well, including
the minimum mass and minimum drag solutions.

Thus the resulting data adds to the available knowledge
concerning the aircraft project in an early design phase.
Moreover, it can be considered a valuable aid in the trade-
-off decision-making processes concerning design driving
requirement parameter values or detail solution versus detail
solution, as an example may demonstrate.

6 Example
In the example below, the search history of a scaling run

is shown for selected key parameters (Figure 5). The auto-
mated scaling process resizes the mentioned cargo aircraft
towards a certain required climb rate by changing engine
static thrust, wing area, and lift coefficient respectively flap
system, thus implicating a change in aircraft total mass. Inter-
actions between lift coefficient and wing geometric properties
are reflected in the calculations. Any of the vertically arranged
parameter combinations in Figure 5 can be regarded as a pos-
sible solution, a result of a scaling core run (with the exception
of iteration 0, which represents the baseline design not yet
fulfilling the improved requirement). It becomes apparent
that the minimum-mass technical approach to improve climb
rate values is to revise the high-lift system, thus allowing wing
size and engine static thrust to shrink.

Relying on this result, the minimum mass solution for an
e.g. 10 % climb rate improvement and the corresponding
mass penalties can be calculated (Table 4). Effects of a 10 %
climb rate reduction can be determined as well (Table 5). With
this data the mass penalties or benefits of the realisation of
a certain climb rate requirement are made obvious. Moreover,
in this example the results indicate that the baseline aircraft
features a certain design improvement potential concerning

96 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

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

Fig. 4: Design diagram with plottings of evaluable solutions



climb rate performance, since even a climb rate-reduced air-
craft shows a possible mass reduction.

Note that the example diagram refers only to the men-
tioned climb rate performance improvements. Additional
constraints, e.g. a shortened landing distance or a changed
mission range performance, would yield different results.

In addition to point performances, different technical
approaches to satisfy a certain mission range requirement can
be investigated as well. In Figure 6, the example baseline
design is scaled in order to accommodate enough fuel for
a given increased outbound range within a complex air sup-
ply mission profile (Figure 3): wing area and/or external fuel
tank size are varied, and the overall changes in mass and zero
drag are determined. It becomes obvious that a wing area
increase is preferable to the installation of external fuel tanks,
which would require pylons and additional piping and come
along with increased zero drag, too.

Relying on this recommended configuration, the mass
and drag penalties for an outbound range increase of e.g.
10 % or 20 % can be investigated, and the required key basic
parameters are provided by scaling runs (Table 6).

To finally include the above mentioned reflection of oper-
ational requirements (Table 3) in the example, the last
column of Table 6 shows the penalties of a required in-flight
refuelling capability, which was realised by integrating an
aerial refuelling probe into the upper forehead of the cargo
aircraft. For the current baseline aircraft, the probe integra-
tion is obviously acceptable, at least in terms of additional
mass and drag.

These examples illustrate how trade-off decisions can
be prepared substantially with the presented scaling
methodology.

7  Conclusion
A computer-based automatic scaling process, which is me-

thodically not restricted to certain aircraft types, is described.
An extended requirement model reflecting point, mission

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

Overall Iterations2

102 %

98 %

85 %

100 %

310

Rel. T/O Mass

Rel. Wing Area

4 5 6

Minimum Mass

Solution

Fig. 5: Search history for climb rate improvement

Climb rate improvement of 10 %
Changes relative to Baseline

Static thrust change –8.0 %

Wing area change –17.0 %

Max lift coefficient change +24.0 %

Overall mass change –2.4 %

Table 4: Climb rate improvement of 10 %

Climb rate reduction of 10 %
Changes relative to Baseline

Static thrust change –7.6 %

Wing area change –15.4 %

Max lift coefficient change 0.0 %

Overall mass change –3.3 %

Table 5: Climb rate reduction of 10 %

Overall Iterations

102 %

100 %

100 %

101 %

10

Rel. Zero Drag

2

Rel. Wing Area

Minimum Mass

Solution

Fig. 6: Search history fors improved mission range

Mission range calculation
Changes relative to Baseline

Range
+10 %

Range
+20 %

Refueling
Probe

� Fuel mass +4.6 % +10.1 % 0.0 %

� Structure mass +4.0 % +6.4 % +0.003 %

� Overall mass +4.25 % +7.9 % +0.001 %

� Wing area +4.3 % +8.6 % 0.0 %

� Fuselage length 0.0 % 0.0 % 0.0 %

� Wetted area +1.7 % +3.4 % +0.002 %

� Zero drag +1.6 % +3.3 % +0.002 %

� Wing loading –0.05 % –0.64 % 0.0 %

� Thrust loading – 4.08 % –7.32 % 0.0 %

Table 6: Mission range calculation



and operational performances has been introduced. An air-
craft is represented in sufficient detail for conceptual design
considerations by a set of variables and methods to enable the
determination of their parameter values. An accordingly de-
fined cargo aircraft model is then automatically resized with
computer aid in the described FASTR approach, until it satis-
fies the extensive, yet freely definable set of requirements in
an optimum solution with respect to a selectable figure of
merit, e.g. overall mass or drag. Results available at the end
of, as well as information gained along the scaling process,
include growth factors and design sensitivities. Relying on this
data, important trade-off decision-making processes during
aircraft conceptual design are enabled and backed up with
extended knowledge about the evolving aircraft.

References
[1] Mavris, D. N., DeLaurentis, D. A.: A Probabilistic Approach

for examining Aircraft Feasibility and Viability. Aircraft De-
sign 3/2000, Pergamon Press, Oxford, 2000

[2] Whitford, R.: The Benefits and Costs of Stealth from the Air-
craft Designer’s Viewpoint. Acta Polytechnica Vol. 40, Janu-
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[3] Roskam, J.: Airplane Design, Part I-VII. DARcorporation,
Kansas, 1988

[4] Torenbeek, E.: Synthesis of Subsonic Airplane Design. Delft
University Press, Delft, 1982

[5] Wittmann, R.: Generisches Modell für propeller- und strahl-
basierte Flugzeugantriebe. Internal Report LT-SA 01/6,
Technische Universität München, Munich, 2001

[6] Schemensky, R. T.: Development of an Empirical Based
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ume 1, Wright-Patterson AFB, Ohio, 1973

[7] Polhamus, E. C.: Prediction of Vortex-Lift Characteristics
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[8] N. N.: USAF Stability and Control DATCOM. Air Force
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[9] N. N.: Luftfahrttechnische Handbücher, LTH-Band Masse-
analyse. IABG, Munich, February 1992

[10] N. N.: ESDU International Structures Series.
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[11 Schieck, F., Deligiannidis, N., Gottmann, T.: A Flexible,
Open-Structured Computer Based Approach for Aircraft
Conceptual Design Optimisation. AIAA Paper 2002-0593,
Washington D.C., 2002

[12] Ballhaus, W. F.: Clear Design Thinking using the Aircraft
Growth Factor. Presentation, SAE Los Angeles Aeronau-
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[13] Burns, J. W.: Aircraft Cost Estimation Methodology for
Preliminary Design Development Applications. Presentation,
SAWE Conference, 23–25 May 1994 (SAWE Paper
No. 2228, Attachment E)

Dipl.-Ing. Florian Schieck
phone: +49 89 289 15986
e-mail: schieck@llt.mw.tum.de

Prof. Dr.-Ing. Dieter Schmitt
phone: +49 89 289 15981
e-mail: schmitt@llt.mw.tum.de
fax: +49 89 289 15982

Chair of Aeronautical Engineering
Technische Universität München
Boltzmannstraße 15, 85748 Garching, Germany

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


	Table of Contents
	Rapid Prediction of Configuration Aerodynamics in the Conceptual Design Phase 3
	C. Munro, P. Krus
	Prospects for Advanced Engineering Design Based on Risk Assessment 8
	M. Holický



	Genetic Algorithm Optimisation of a Ship Navigation System 13
	E. Alfaro-Cid, E. W. McGookin, D. J. Murray-Smith
	Conceptual Design of a Hydraulic Valve Train System 20
	J. Pohl, A. Warell, P. Krus, J.-O. Palmberg



	Analysis of a Thermal Plasma Diamond CVD System 29
	D. Kolman

	Fatigue Crack Initiation and Early Growth in GLARE 3 Fiber-metal Laminate Subjected to Mixed Tensile and Bending Loading 33
	A. Chlupová, J. Heger, A. Vašek

	Involvement of Thermodynamic Cycle Analysis in a Concurrent Approach to Reciprocating Engine Design 37
	J. Macek, M. Takáts

	The Validation of Computer-based Models in Engineering: Some Lessons from Computing Science 45
	D. J. Murray-Smith

	Control System Design Based on a Universal First Order Model with Time Delays 49
	T. Vyhlídal, P. Zítek
	Stress Distribution in a Coal Seam before and after Bump Initiation 54
	J. Vacek



	Computational Investigation of Flows in Diffusing S-shaped Intakes 61
	R. Menzies
	Improving Aircraft Design Robustness with Scenario Methods 68
	A. Strohmayer

	Credibility of Design Procedures 74
	J. Marková, M. Holický 



	Aerodynamic Design of a Tailless Aeroplan 79
	J. Friedl

	Structural Design Using Simulation Based Reliability Assessment 85
	S. Vukazich, P. Marek

	Cargo Aircraft Conceptual Design Optimisation Using a Flexible Computer-Based Scaling Approach 93
	F. Schieck, D. Schmitt