AP06_5.vp


1 Introduction
The vision and image processing systems are widely em-

ployed in current manufacturing processes. These kinds of
systems provide measures to inspect and control the manu-
facturing process of the producing location. In addition,
the vision systems make automatic inspection and process ex-
amination possible with the help of “intelligent” software
components. The project, on which this paper is based, is
initiated in such a circumstance in order to associate and sim-
plify the qualtiy control of free-form surface manufacturing,
specially shining water taps in sanitary industries.

The first stage in the fabrication of water taps is the casting
of the rough part. The material that is mainly used is brass.
After the casting process some other machining processes,
like drilling, milling and threading are carried out. Then the
water tap is ground and polished sequentially in order to
obtain high surface quality. Finally, the end product is finished
by electroplating. It is crucial to find out the potential defects
existing on the workpiece surface after grinding and polish-
ing before the final electroplating. If a defect is found on
a part after electroplating, manufacturer has to painfully
discard this part or remove the electroplated coating. In this
case removing the coating is a very expensive process because
its harmful to the evironment. Therefore cost will be saved if
the defects can be detected at an early stage. In addition, it is
always useful to find out which type of a defect has been iden-
tified. Once the type of a defect is known, the decision can
be made whether the part is discarded or can be retouched
with proper compensatory engineering processes and if an
adjustment of a previous machining process is necessary.

So far the tasks of defect inspection and categorization
are performed by human operators in a traditional “see and
evaluation” way. It is a labour-intensive and therefore also
cost-intensive job. This process is necessarily automated to
improve the efficiency of defects inspection, releasing worker
from unpleasant working environments, and finally reducing
the overall manufacture cost, specially in the countries where
wages are high. To automate the defects inspection and classi-
fication, a vision system is installed and integrated into the
manufacturing chain. In our project, the inspection process
takes place after the end of the grinding and polishing pro-

cesses. If no defects are found on the surface, the workpiece is
accepted for the next processing step. Otherwise, it is classi-
fied automatically in order to determine if a removal of the
defect is possible or the workpiece should be rejected directly.

The vision system consists of a carrier, a camera system, a
lighting system, other accessories and the software. The sys-
tem hardware is responsible to provide a constant lighting
enviroment and obtain the digital images under this constant
circumstance. The software provides the solution to examine
the images from the camera system, locating and classifing
the defects on workpiece surfaces.

The challenge in our project now is to characterise and
determine the type of defects from predefined categories
and additional foulings (which are called pseudo-defects in
our project) on the surface. To this end, this paper presents
measures and considerations regarding both theoretical and
practical aspects, to efficiently classify all defects as well as a
separation of real-defects from pseudo defects.

2 Automatic classification system

2.1 Defects definition
The defects have been generally divided into 15 classes

according to their physical attributes and the consequent
handling operations. Fig. 1. gives samples for all defect cate-
gories. All defects mainly can be split up into two major
categories, real-defects and pseudo-defects that are actually
foulings, like dust or oil, on the surface or shades caused
by uneven lighting on the free-form surfaces. The first ten
defects in Fig. 1. are real-defects and the last five are pseudo-
-defects. The pseudo-defects are causing no quality problem;
while the real-defects should be critically picked out because
they not only spoil the aesthetic aspect but sometimes also
result in malfunction of final products. The vision system con-
siders both kinds as failures at first and distinguish them in
the classification phase. Therefore, two indice have to be
taken into account, the overall right classficaition ratio and
wrong classification ratio between the real-defects and pseu-
do-defect. In addition, the wrong classification ratio from
real- to pseudo-defects is more crucial than that from pseu-
do- to real-defects. In the previous case, a product with real-

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Acta Polytechnica Vol. 46  No. 5/2006

Quality Control in Automated
Manufacturing Processes – Combined
Features for Image Processing
B. Kuhlenkötter, X. Zhang, C.Krewet

In production processes the use of image processing systems is widespread. Hardware solutions and cameras respectively are available for
nearly every application. One important challenge of image processing systems is the development and selection of appropriate algorithms
and software solutions in order to realise ambitious quality control for production processes. This article characterises the development of
innovative software by combining features for an automatic defect classification on product surfaces. The artificial intelligent method
Support Vector Machine (SVM) is used to execute the classification task according to the combined features. This software is one crucial
element for the automation of a manually operated production process.

Keywords: quality control, image processing, defect classification, support vector machine.



1 Introduction

The use of computers is essential in modern design pro-
cesses. Computer Aided Design (CAD) is extensively applied
in a wide range of industrial branches. However, there is a
body of opinion that the benefits of applying CAD are below
expectations. The development of CAD systems and their
applications in engineering practice have been greatly influ-
enced in the last decade by rapid increases in the perfor-
mance of computer hardware. Emphasis has been laid on the
implementing numerical methods and computer graphics.
Hence, CAD still concentrates rather too much on providing
a means for representing the final form of design, where-
as designers also need a continual stream of advice and
information.

Design problems are known to be “ill–defined”. The prob-
lem statement usually sets a goal, some constraints within
which the goal must be archived, and some criteria by which
a successful solution might be recognised. The solution is
unknown, and there is no certain way of proceeding from
the statement of the problem to a statement of the solution.
Moreover, many design constraints and criteria also remain
unknown and existing CAD approaches, based on conven-
tional programming methods, are not able to help the de-
signer in dealing with uncertainty and inconsistencies. Thus,
the quality of design solutions still depends mostly on the
designer’s skill and experience.

It can be argued that not many successful intelligent sys-
tems are known to be applied in engineering domains, espe-
cially not in the field of design optimisation. Until recently,
engineering (design) problems were indeed considered as
well-defined mathematically-formulated problems, that can
be managed with the computer aids based on numeric repre-
sentation and computer graphics, without ‘interference’ from
artificial intelligence. However, it is becoming more and more
evident that adding intelligent behaviour to the existing CAD
tools [1] can lead to significant improvements in the effective
and reliable performance various engineering tasks, includ-
ing design optimisation.

In this paper, we will present three different intelligent
modules to be applied within a design process to enable more
intelligent and less experience-dependent design optimisa-
tion. A computer-aided geometric modeller and a structural

analysis package are basic CAD tools within the proposed
optimisation cycle. The design cycle begins with the initial
design and problem definition. The first intelligent module is
applied to support the preparation of the numerical model
for structural analysis. After the analysis, the second intelli-
gent module is provided to support evaluation of the “expert”
results, upon which the most appropriate design optimisation
steps are defined. The final design is usually reached after
several structural analyses, and each run involves appropri-
ately adjusted input data, including design changes if neces-
sary. The third intelligent module addresses more specific
design issues related to ergonomic and aesthetic aspects of
the design. This will be used by the designer when specifying
the outer geometric shape and appearance of the product.

2 Design optimisation
Design optimisation is a very complex iterative process. In

many cases, the basic parameters for the optimising process
are the results of structural engineering analysis. Finite Ele-
ment Analysis (FEA) [2] is the most frequently used numerical
method for simulation and verification of the conditions in
the structure. If the structure does not satisfy given criteria,
certain optimisation steps, such as redesign, use of other
materials, etc., have to be taken. The initial design is made in
a geometric modeller, analysed by FEA or some other method
for engineering analysis and then re-designed in the model-
ler. This optimisation loop is repeated until the final design,
that satisfying the given criteria, is developed.

Since existing CAD tools fail to provide functional ad-
vice, the quality of the initial design, analyses and re-design
actions, and also the number of iterative steps needed to
reach the final solution depend mainly on the designer’s ex-
perience. Design experts can efficiently perform structural
design optimisation. They have built up their experience over
time by working on design and analysis problems for various
products. Their strategy when dealing with a design problem
is based mainly on heuristics or rules of thumb. But what
about less experienced designers? Is it possible to avoid trial-
-error behaviour and help them to perform computer-aided
design optimisation more efficiently? Evidently, traditional
design optimisation systems that concentrate on numerical
aspects of design process are not successful in integrating
numerical parts with human expertise [3].

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Acta Polytechnica Vol. 46  No. 5/2006

Intelligent Support for a Computer
Aided Design Optimisation Cycle

B. Dolšak, M. Novak, J. Kaljun

It is becoming more and more evident that adding intelligence to existing computer aids, such as computer aided design systems, can lead to
significant improvements in the effective and reliable performance of various engineering tasks, including design optimisation. This paper
presents three different intelligent modules to be applied within a computer aided design optimisation cycle to enable more intelligent and less
experience-dependent design performance.

Keywords: knowledge based systems, computer aided design, structural analysis, ergonomics, aesthetics.



3 Intelligent design optimisation
cycle
In order to make thee design optimisation process more

intelligent and less experience-dependent, existing CAD sys-
tems should be supplemented with some intelligent modules
that will provide advice when needed. In the last decade, vari-
ous Artificial Intelligence (AI) applications to engineering
design have been reported. The book edited by D. T. Pham
[1] is a good collection of early examples related to this area. It
is evident that AI applications to design are now the subject of
intensive development and implementations. Fig. 1 shows
our proposal for an intelligent design optimisation cycle,
based on interaction between a geometric modeller and an
FEA package.

The idea is to encode the knowledge and the experience
required in dealing with engineering design optimisation into
a Knowledge Base (KB) that can be used by a computer sys-
tem. The proposed intelligent KB modules should help the
user to reach a final design that will fulfil the structural and
other specific design criteria. The optimisation cycle begins
with the problem definition and initial design. The first KB
module is applied to support the user in the process of setting
the Finite Element (FE) mesh parameters. After the initial
FEA is performed, the second intelligent module is involved
to perform an evaluation of the “expert” results. For every
iterative analysis, the input data is corrected and/or the struc-
ture is re-meshed before a new analysis is performed. If the
geometry of the structure needs to be optimised, design
changes are also performed before returning to the pre-pro-
cessing phase of the analysis.

A special group of intelligent KB modules is envisaged
to support the various design tasks in the geometric model-
ler in order to satisfy more specific design criteria, such as
manufacturability, appropriateness for assembly, ergonomics,
aesthetics, etc.

As is shown in Fig. 1, the idea is to link the existing
FEA package and geometric modeller with the proposed KB
modules into an integrated intelligent software environment
for design optimisation. In addition, for proper integration
leading to a transparent and user-friendly optimisation tool,
several interfaces need to be developed to ensure that the
data is always converted to the format used in the next step of
optimisation.

Now we will discuss in greater detail, three KB modules
that are important composite parts of the proposed intelli-
gent design optimisation cycle. Two of them are strongly
related to the structural analysis part of the optimisation
process, while the third KB module contains more specific
knowledge to support the designer in setting the ergonomic
and aesthetic value of the new product. All three intelligent
systems mentioned here are under of research and develop-
ment in our laboratory.

4 KB module for finite element mesh
design
Within FEA, a number of different mesh models usually

need to be created until the right one is found. The trouble is
that each mesh has to be analysed, since the next mesh is
generated with respect to the results derived from the previ-
ous mesh. Considering that one FEA can take from a few

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Acta Polytechnica Vol. 46  No. 5/2006

manufacture, assembly,

Fig. 1: Intelligent design optimisation cycle



minutes to several hours and even days of computer time,
there is obviously a strong motivation to design “optimal”
finite element mesh models more efficiently – in the first
step or at least with minimum trials. As an alternative to
the conventional “trial-and-error” approach to this problem,
we have developed the Finite Element Mesh Design Expert
System named FEMDES [4]. The system was designed to
help the user to define the appropriate finite element mesh
model more easily, more rapidly, and with less dependence on
experience.

FEA has been applied extensively for more than 30 years.
However, there is no clear and satisfactory formalisation of
the mesh design know-how. Finite element design is still a
mixture of art and experience, which is hard to describe
explicitly. However, many resorts have been published in
terms of problem definition, an adequate finite element mesh
(chosen after several trials), and results of the analysis. These
reports were used as a source of training examples for ma-
chine learning algorithms to construct more than 1700 rules
for finite element mesh design by generalising given
examples. The way in which inductive logic programming
techniques were applied to develop the KB in this particular
case is presented in detail in [5].

Fig. 2 shows how FEMDES is to be applied within the FEA
pre-processing phase. The user has to define the problem (ge-
ometry, loads, and supports). The data about the problem
needs to be converted from the FEA pre-processor format
into the symbolic qualitative description to be used by the KB
module. FEMDES’ task is to propose the appropriate types of
finite elements and to determine the mesh resolution values.
A command file for the mesh generator can be constructed
according to the results obtained by the intelligent system.

For FEMDES, we have built our own program to gain the
most efficient correlation between the knowledge and the
program part of the system. Like the KB, the shell is also writ-
ten in Prolog. This enables the proper use of the KB for FE
mesh design (inference engine), and also communication be-
tween the user and the system (user interface). A very impor-
tant and useful feature of the user interface is its capability to
explain the inference process, by answering the questions
“Why?” and “How?” A complete source code of the program,
together with explanations of the algorithms performed by
the program, can be found in [6].

The user has to prepare the input data file before running
the system. The structure that is to be analysed needs to be
described in exactly the same way as the training examples
were presented to the learning algorithm in the knowledge
acquisition phase. This can be done automatically by using

the geometric model of the structure. Guidelines for auto-
matic transformation from numeric form to symbolic qualita-
tive description are presented in [6]. However, FEMDES is not
yet integrated with any commercial FEA pre-processor. Thus,
the problem description currently needs to be made manu-
ally. This takes some time, especially for structures that are
more complex. However, following a few simple algorithms
the task does not require special knowledge and experience.

To simplify the learning problem, the training set used for
developing of the knowledge base was designed with the aim
of being representative of a particular type of structures. The
following limitations were taken into account:
� all structures were cylindrical,
� only forces and pressure were considered as loads,
� highly local mesh refinement was not required.

However, FEMDES can also be applied as a general tool
for determining the mesh resolution values for real-life three-
-dimensional structures outside the scope of these limitations.
The results of the system have to be adjusted subsequently,
according to the specific requirements of the particular analy-
sis. Furthermore, they can always serve as a basis for an initial
FE mesh, which is subject to further adaptations considering
the results of the numerical analyses. It is very important
to choose a good initial mesh and to minimise the number of
iterative steps leading to an appropriate mesh model. Thus,
FEMDES can be very helpful to inexperienced users, espe-
cially through its ability to explain the inference process.

5 KB module for structural
analysis-based design improvements
The post-processing phase of the engineering analysis

represents a synthesis of the whole analysis and is therefore of
special importance. It concludes with the final report of the
analysis, where the results are quantified and evaluated with
respect to the next design steps, which have to follow, the
analysis in order to find an optimal design solution. The
sources for post-processing are numerical results of the com-
putation performed in the previous phase of the analysis.
The data is stored in a computer file. In spite of the fact that
the records are quite well ordered, the numerical figures are
hard to follow in the case of a complex real-life problem, when
the data file is usually complex and extensive. Nowadays FEA
software is very helpful at this point, as it offers adequate com-
puter graphics support in terms of reasonably clear pictures
showing the distribution of the unknown parameters inside
the body of the structure.

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Acta Polytechnica Vol. 46  No. 5/2006

Fig. 2: FEMDES application within the FEA pre-processing phase



However, the user still has to answer many questions and
solve many dilemmas in order to conclude the analysis and
compose the report. The designer has to be able to judge
whether the results of the analysis are correct and reliable,
and also to decide what kind of design changes are needed,
if any. Most users need “intelligent” advice to interpret the
analysis of the results adequately. Unfortunately, this kind of
help cannot be expected from the present software. Tradi-
tional systems tend concentrate on numerical aspects of the
analysis and are not successful in integrating the numerical
parts with human expertise.

In order to overcome this bottleneck, we decided to collect
and encode the knowledge and experience needed to pro-
pose appropriate design actions that may lead to design
improvement. In this way the prototype of the intelligent con-
sultative system PROPOSE for supporting design decisions
considering the results of a prior stress/strain or thermal anal-
ysis was developed [7]. PROPOSE provides a list of redesign
recommendations that should be considered in order to opti-
mise a certain critical area within the structure.

Fig. 3 shows that, as a result of applying PROPOSE the
user may expect a list of redesign recommendations, based on
the expert interpretation of the results of the prior numerical
analysis. As a rule, several redesign steps are possible for
design improvement. The selection of one or more redesign
steps to be performed in a certain case depends on require-
ments, possibilities and wishes.

The proposed system was developed in several steps. The
most important step was to develop the knowledge base,
where knowledge acquisition was the most crucial task [8].
Theoretical and practical knowledge about design and rede-
sign actions were investigated and collected. A wide range
of different knowledge is needed to explore possible design
actions that should follow the engineering analysis. Knowl-
edge acquisition was carried out in three different ways:
from a literature survey, from examinations of old engineer-
ing analyses and from interviews with human experts. That
was not an easy task. Recommendations on redesign are
scarce, and are dispersed in many different design publica-
tions. Many reports on analyses contain confidential data and
cannot be used. On the other hand, interviews and examina-
tion of existing redesign elaborations depend on cooperation
with experts, and can be time-consuming. Therefore, the
scope of the results is greatly limited by the experts.

Production rules were selected as an appropriate formal-
ism for encoding knowledge, because they are quite similar to
the actual rules used in the design process. Each rule proposes
a list of recommended redesign actions that should be taken

into consideration, while dealing with a certain problem, tak-
ing into account some specific design limits. The rules are
generalised, and do not refer only to the examples that were
used during the knowledge acquisition process. They can be
used whenever the problem and the limits match with those
in the head of the rule. In such a case, applying of the ap-
propriate rule will result in a list of recommended redesign
actions for dealing with the given problem.

When using the PROPOSE system, the user has to answer
some questions stated by the system in order to describe the
results of the engineering analysis. In addition, critical areas
within the structure need to be qualitatively described to the
system. This input data is then compared with the rules in the
knowledge base, and the most appropriate redesign changes
to be taken into account in a given case are determined
and recommended to the user. The system provides constant
support to the user’s decisions in terms of explanations and
advice. Finally, the user receives an explanation of how the
proposed redesign changes were selected and also some more
precise information on how to implement a certain redesign
proposal, including some pictorial explanations. Fig. 4 shows
an example of such an explanation for the proposed design
action: “add smaller relief holes in the line of loads on both sides of the
problem hole”.

The abstract description of the problem area should be as
general as possible, in order to cover most the problem areas,
instead of addressing only very specific products, which is
characteristic of some recent research projects in this field

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Acta Polytechnica Vol. 46  No. 5/2006

Fig. 3: PROPOSE application within the FEA post-processing phase

Fig. 4: Example of a pictorial explanation of a redesign action
recommended by PROPOSE



[9–11]. For this reason, the number of predefined attributes is
relatively small. However, by answering some additional ques-
tions, the problem can be defined in a more refined manner.
In cases when the problem area can be described to the system
in different ways, it is advisable to run the system several
times, each time with a different description. Thus, the system
will be able to propose more design actions, at the expense of
only a few more minutes at the console. The larger number of
proposals may confuse the user, who will probably need help
in the form of explanations of the proposals. On the other
hand, more proposals will provide more options for design
improvements.

The PROPOSE system was evaluated in two ways. First,
experts who had already been involved in the knowledge
acquisition process evaluated the system. Then some real-life
examples were used to test the performance of the system.
The experts that participated in the evaluation process are
practising designers and some academics. They individually
evaluated the system from two points of view. First, they
analysed the performance of the system using some real-life
examples. They also evaluated the user interface by inspect-
ing how well the system helps and guides the user, or even
enables him or her to acquire some new knowledge. The suit-
ability, clearness and sufficiency of the redesign proposals
were also evaluated. All comments, critiques and suggestions
presented by the experts were taken into consideration and
led to numerous corrections and adjustments of the system.

6 KB module for ergonomic and
aesthetic design
In order to deliver suitable design solutions, designers

have to consider a wide range of influential factors. Ergo-
nomics and aesthetics are certainly among the most complex
considerations. Less experienced designers could meet sev-
eral problems in the design stage. Some computer tools are
available to be used for evaluating of the ergonomic condition
of the product [12]. However, much experience and knowl-
edge in the field of ergonomics is required in order to choose
and carry out the appropriate redesign actions to improve the
ergonomic value of the product within a reasonable time. On
the other hand, the aesthetic design phase still depends
mainly on the skill and experience of the designer and is not
supported by any computer tool of any practical value.

In this context, we decided to develop an intelligent con-
sultative system that will be able to support the designer
through the decision making process when defining the ergo-
nomic and aesthetic parameters of the product [13]. Expert
advice is clearly often needed, and it could be very useful

to apply the intelligent advisory system. Moreover, since the
aesthetic and ergonomic properties of the product are estab-
lished in the early phases of product development, the intelli-
gent advisory system should be able to support this process
with minimum data requirements. The ergonomic analysis
and aesthetic evaluation should be performed on the CAD
model. After that, the intelligent system can be used again to
advise the user which design changes are possible or even
necessary in order to improve the ergonomic and/or aesthetic
value of the product.

In order to improve the ergonomic and aesthetic value of
the product, the design recommendations will be proposed to
the user by using the expert knowledge collected in the KB of
the system and the case-specific data given by the user. For
proper control over each part of the system, we decided to
build two separate knowledge bases, containing the theoreti-
cal and practical knowledge about the design and redesign
actions, one for the ergonomic part and the other for the
aesthetic part of the system. If the user applies only one part
of the system, the inference engine will be able to use the
separate KB that belongs to that part. On the other hand, if
the complete system is used, both knowledge bases will be
used, while some special rules will be applied to harmonise
the ergonomic and aesthetic design recommendations, when
necessary (Fig. 5).

The KB module for ergonomic and aesthetic design, dis-
cussed in this section, is still under intensive research and
development. Currently we are working on development the
KB for the ergonomic part of the system, where we have lim-
ited the target area to hand tool design. In this context, the
global hand tool ergonomic design goals [14] that need to be
followed by the designer of the hand tool in order to meet
health, safety and efficiency requirements, have been speci-
fied. The following are some of the goals recognised as most
important:

� consider the anthropometrical data to define the dimen-
sions and configurations;

� maintain the wrist in the neutral straight position;
� avoid tissue compression;
� reduce the excessive forces;
� protect against vibration, heat, cold and noise;
� ensure that the task can be performed at the appropriate

height;
� reduce the static load;
� consider cognitive ergonomics.

The KB that is being developed will contain rules on how
to realise these goals within the hand tool design.

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Acta Polytechnica Vol. 46  No. 5/2006

Fig. 5: Intelligent support to ergonomic and aesthetic design



7 Conclusions
Engineering design is obviously much more than just

analysis and modelling, and existing CAD systems need to be
further explored to be able to assist in the other aspects of
design as well. Future research and development of CAD
systems will require radical re-thinking, considering some
new approaches that have not been taken properly into ac-
count in the past. The application of AI techniques in design
is certainly an approach that is becoming more and more
important.

Design optimisation is a part of the development process
for almost every new product. It plays a very important role in
the modern high-tech world, where only optimal solutions
can win the game on the market. However, developing opti-
mal design solutions is a very complex domain that cannot be
treated adequately by using conventional CAD tools, unless
the user possesses special skills and experience. Thus, many
research activities are aimed at making the design optimisa-
tion process more intelligent and less experience-dependent.
Many experts share the opinion that this can be achieved by
supplementing existing CAD systems with some intelligent
modules that will provide advice when needed. The intelli-
gent modules discussed in this paper are important parts of
the overall intelligent design optimisation cycle and are now
under intensive research and development in our laboratory.

Design data is not always well formulated, and almost
never complete. Humans can deal with such data reasonably
easily, while even the most “intelligent” programs have great
difficulties. Designers are also reluctant to assign responsi-
bility for decisions to computer programs, no matter how
competent they may appear. it can also be argued that an en-
coded design KB does not allow designers to express their
creative ideas. All these and many other factors constrain the
application of intelligent systems in design. Therefore, it is
likely that no single technology will be adequate by itself.
The designer will have available a toolkit of techniques, in-
cluding intelligent modules, for information and well-defined
advice for making decisions and judgements. Our research
presented here takes a step or two forward on the way intel-
ligent support for the design process.

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Ergonomics. Engineering Designer, Vol. 25 (1999), No. 2,
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[13] Kaljun, J., Dolšak, B.: Computer Aided Intelligent
Support to Aesthetic and Ergonomic Design. WSEAS
Transactions on Information Science and Applications, Vol. 3
(2006), No. 2, p. 315-321.

[14] Noyes, J. M.: Designing for Humans. Hove Press, 2001.

Dr. Bojan Dolšak, univ. dipl. Ing.
e-mail: dolsak@uni-mb.si

Dr. Marina Novak, univ. dipl. Ing.

Jasmin Kaljun, univ. dipl. Ing.

Laboratory for Intelligent CAD Systems

University of Maribor
Faculty of Mechanical Engineering
Smetanova 17
SI-2000 Maribor, Slovenia

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Acta Polytechnica Vol. 46  No. 5/2006