Acta Polytechnica CTU Proceedings


doi:10.14311/APP.2017.12.0010
Acta Polytechnica CTU Proceedings 12:10–12, 2017 © Czech Technical University in Prague, 2017

available online at http://ojs.cvut.cz/ojs/index.php/app

QFD EXAMPLE IN INTERACTION WITH HMI

Inga Chudjakova∗, Jaromír Tobiška

ŠKODA AUTO a.s., Tř. Václava Klementa 869, Mladá Boleslav, 293 60, Czech Republic
∗ corresponding author: Inga.Kadlecova@skoda-auto.cz

Abstract. This article focuses on the application of the Quality Function Deployment (QFD) method
and shows how we can use this method in the automotive industry. The cockpit of the modern car
is still developing and changing according to technical progress and customers’ requirements. The
QFD method enables the setting of the customers’ requirements and then puts them into technical
expression. The matrix of QFD sets those technical expressions that are the most important properties
customers expect. These chosen properties can be tested during the technical development. The testing
of new HMI concepts goes through a driving simulator and can suggest which one is suitable for being
used in a real car.

Keywords: the QFD method, customers’ requirements, automotive industry, DoE, HMI, driving
simulator, House of Quality.

1. Introduction
Nowadays in the automotive industry, the aim of all
car producers is customer satisfaction, but also techni-
cal progress, that can differentiate them in the current
competitive environment. A set of quality methods
serves/is used to achieve customer satisfaction in the
automotive industry. They lead to production of
high-quality production and are also related to higher
profit.

2. Quality Assurance Methods
For the reasons above it is necessary to use the quality
assurance methods in the automotive industry and
use them at the beginning of the product development
process. The QFD method, i.e. Quality Function
Deployment, is one of these methods. This method
is used mostly at the first stage of the product de-
velopment process because the QFD method allows
transformation of customer requirements into techni-
cal expression[1]. Its main task is the determination
of customer requirements and their implementation
in the process of the product preparation. Thanks
to QFD methods, the designers can understand what
customers want and it designs the product.

The methods used for optimizing the costs and the
methods to prevent errors and faults in the develop-
ment of a product also belong among the assurance
methods. For more detailed classification of the qual-
ity assurance methods overview see the Fig. 1.
By using QFD method(s) we can assess the fulfil-

ment of the customers’ requirement for products and
processes. At the start of the QFD method applica-
tion, there are the customer’s requirements (wishes).
To find out what the customers want we need to focus
on the following:

a)Technical parameters, a physical element, a speci-
fied part of system

Figure 1. The quality assurance methods overview.

b)Defined procecesses, assembly operations, handling
operations, specific actions

Figure 2. The QFD application.

The use of the QFD method is equal in the both
cases. The difference is in the outcomes. We are able
to find the key element of the system and the specific
technical parameter, which we monitor to ensure the
fulfilment of customers’ requirements or key activities;
the process which implementation may impact the
consequences effecting the customers’ satisfaction.

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vol. 12/2017 QFD Example in Interaction with HMI

3. The Application of the QFD
Method

The basic outcomes of the QFD (Quality Function
Deployment) method application are the answers to
the two following questions:

• What are the customer’s expectations?
• How can we meet these expectations? [1]

The QFD method is characterized by four applica-
tion stages, which are as follows: Product proposal
(a proposal of characteristic product properties), pro-
posal of components, processes planning and produc-
tion planning. Each of these stages is noted in a
diagram and matrixes.

3.1. Matrixes of the QFD Method
The QFD method is based on the QFD matrix, which
is often marked as the "House of Quality" and consists
of a team of experts. The overall structure of the
QFD matrix has 8 specified fields, but during the use
the QFD matrix not all fields need to be completed.
It is possible to use only a part of the QFD matrix,
as required by the project. The QFD matrix that
describes the most important field, can be seen at the
graph bellow (see Fig. 3).

Figure 3. QFD matrix "The house of Quality".

For the completing of the QFD matrix it is not
required to use a special programme or software, one
can just fill an Excel table.
The most important thing for the using the QFD

method and filling in the QFD matrix is to know the
succession of inputs and outputs – for detail see Fig.
4.

The QFD method can interpret the customers’ re-
quirements, which are often defined only verbally, into
the technical values that the designers can work with.
To use the QFD method correctly, it is essential to get
the inputs. This information can be obtained from:

• Surveys/Questionnaires
• Thinking loud (Lautes Denken)

Figure 4. QFD method relations.

• Clinical studies
• Group discussions/Think tanks ???
• J. D. Power

These procedures are established in quantitative
and qualitative research techniques. In order to receive
the information needed, it is necessary to choose the
right method, group of respondents, questionnaire,
and also the form of responses for each project. The
application of the entire QFD method is based on
obtaining these input data.
Then the matrix is completed with technical solu-

tions that could have an influence on the customers’
requirements. The technical parameters may be de-
fined by using accurate parameters or units. Therefore,
the best technical solutions are those that influence
several customer wishes at once.
The correlation between the customers’ expecta-

tions and the technical parameters is placed in the
main field of the QFD matrix. This mutual corre-
lation shows how much the technical solution will
influence the customers’ expectations. The mutual
influence may have the following values: 0 = no
influence, 1 = low influence, 3 = average influence,
or 9 = huge influence.

4. A Practical Example of
Application of the QFD
Method in the Automotive
Industry

At the present time, the load of the driver while driv-
ing is increasing. This is caused by the improvement
of technology and development of the HMI systems
in cars. Also, the proportion of displaying and con-
trolling components in the cockpit is increasing.
An interaction between these car systems, display-

ing components and a driver may affect driving safety
in a remarkable way[2]. For the practical example of
using QFD method, we need to optimize the display
to ensure safe operation while driving. For setting of
the car display properties of we used QFD method.

In order to use the QFD method, firstly we needed
to find out which display properties customers found
the most important. These were the inputs into the
QFD matrix and we had used the qualitative and quan-
titative techniques and methods. The input data were
received due to an evaluation of the questionnaires,

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Inga Chudjakova, Jaromír Tobiška Acta Polytechnica CTU Proceedings

where respondents assessed the general properties of
a display independent of the tested concepts. For
these customers’ expectations, the technical experts
set the technical parameters, which is are in the field
P4. Then the teams set the correlations between the
customers’ expectations and technical parameters at
the field P5. After the calculations of QFD matrix,
in the field P6 we can see which technical parameters
had effected the customers’ expectations the most.

Figure 5. Example of QFD matrix.

The highest rated technical expressions from the
QFD matrix were tested in the technical clinic through
a driving simulator. In these clinics, the highest rated
expressions were: a font size, font legibility, text un-
derstanding and contrast. These parameters were
tested separately on a separate screen.

Several chosen screens from the display menu were
tested. They display various combinations of the script
sizes and contrast. The respondents were expected
to assess the individual items on each screen, such as
a script legibility, text comprehension and contrast.
The above-mentioned testing revealed that the best
combination of good display legibility for customers is
the second biggest letter size of the tested script with
combination of the best contrast (contrast 1), because
the biggest font size can be distracting[3].

Figure 6. Combination of fontsize and contrast.

5. Conclusion
The QFD method is an integral part of a product
development in the automobile industry. Its contribu-
tion is provable in all the stages of the car development
process as well as in the area of the HMI concept test-
ing. The main objective of the HMI systems testing

is the minimization of the time that these systems
are controlled and thus the time that the driver is
not concentrating on driving. Together, these meth-
ods contribute to customers’ satisfaction, which has
been nowadays emphasized more and more in the
automotive industry.

References
[1] J. Machan, J. Tobiška, et al. Metody kvality užívané
ve fázi vývoje výrobku – aplikace v automobilovém
průmyslu. II.a revised and expanded edition, Prague
2012, 117 p., ISBN 978-80-87042-50-2.

[2] M. Novák, P. Bouchner, J. Faber, et al. Senioři za
volantem. Prague: Faculty of Transportation Sciences,
Czech Technical University in Prague, 2008, ISBN
978-80-87136-20-7.

[3] Zvláštní projekty elektrostrategie a výzkumu, Technický
vývoj, Škoda Auto a.s.: Projekt HMI ve ŠKODA AUTO.
(prezentace), Mladá Boleslav, an internal document,
2013.

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	Acta Polytechnica CTU Proceedings 12:10–12, 2017
	1 Introduction
	2 Quality Assurance Methods
	3 The Application of the QFD Method
	3.1 Matrixes of the QFD Method

	4 A Practical Example of Application of the QFD Method in the Automotive Industry
	5 Conclusion
	References