Introduction
Product design on today's markets has become increasingly complex since products contain more functions and have to meet increasing demands such as user-friendliness, manufacturability and ecological considerations. With a shortenedHistory
Nowadays, people want to use products that are functional at the physical level, usable at the psychological level and attractive at the subjective, emotional level. Affective engineering is the study of the interactions between the customer and the product at that third level. It focuses on the relationships between the physical traits of a product and its affective influence on the user. Thanks to this field of research, it is possible to gain knowledge on how to design more attractive products and make the customers satisfied. Methods in affective engineering (or Kansei engineering) is one of the major areas of ergonomics (human factor engineering ). The study of integrating affective values in artifacts is not new at all. Already in the 18th century philosophers such asProcedure
As mentioned above, Kansei engineering can be considered as a methodology within the research field of 'affective engineering'. Some researchers have identified the content of the methodology. Shimizu et al. state that 'Kansei Engineering is used as a tool for product development and the basic principles behind it are the following: identification of product properties and correlation between those properties and the design characteristics'. According to Nagasawa, one of the forerunners of Kansei engineering, there are three focal points in the method: # How to accurately understand consumer Kansei # How to reflect and translate Kansei understanding into product design # How to create a system and organization for Kansei orientated designA model on methodology
In Japanese publications, different types of Kansei engineering are identified and applied in various contexts. Schütte examined different types of Kansei engineering and developed a general model covering the contents of Kansei engineering. ; Choice of Domain ''Domain'' in this context describes the overall idea behind an assembly of products, i.e. the product type in general. Choosing the domain includes the definition of the intended target group and user type, market-niche and type, and the product group in question. Choosing and defining the domain are carried out on existing products, concepts and on design solutions yet unknown. From this, a domain description is formulated, serving as the basis for further evaluation. The process is necessary and has been described by Schütte in detail in a couple of publications. ; Span the Semantic Space The expression ''Semantic Space'' was addressed for the first time by Osgood et al.. He posed that every artifact can be described in a certain vector space defined by semantic expressions (words). This is done by collecting a large number of words that describe the domain. Suitable sources are pertinent literature, commercials, manuals, specification list, experts etc. The number of the words gathered varies according to the product, typically between 100 and 1000 words. In a second step the words are grouped using manual (e.g. Affinity diagram) or mathematical methods (e.g. factor and/or cluster analysis). Finally a few representing words are selected from this spanning the Semantic Space. These words are called "Kansei words" or "Kansei Engineering words". ; Span the Space of Properties The next step is to span the Space of Product Properties, which is similar to the Semantic Space. The Space of Product Properties collects products representing the domain, identifies key features and selects product properties for further evaluation. The collection of products representing the domain is done from different sources such as existing products, customer suggestions, possible technical solutions and design concepts etc. The key features are found using specification lists for the products in question. To select properties for further evaluation, a Pareto-diagram can assist the decision between important and less important features. Synthesis In the synthesis step, the Semantic Space and the Space of Properties are linked together, as displayed in Figure 3. Compared to other methods in Affective Engineering, Kansei engineering is the only method that can establish and quantify connections between abstract feelings and technical specifications. For every Kansei word a number of product properties are found, affecting the Kansei word. ; Synthesis The research into constructing these links has been a core part of Nagamachi's work with Kansei engineering in the last few years. Nowadays, a number of different tools is available. Some of the most common tools are : * Category Identification * Regression Analysis /Quantification Theory Type I * Rough Sets Theory * Genetic Algorithm * Fuzzy Sets Theory ; Model building and Test of Validity After doing the necessary stages, the final step of validation remains. This is done in order to check if the prediction model is reliable and realistic. However, in case of prediction model failure, it is necessary to update the Space of Properties and the Semantic Space, and consequently refine the model. The process of refinement is difficult due to the shortage of methods. This shows the need of new tools to be integrated. The existing tools can partially be found in the previously mentioned methods for the synthesis.Software tools
Kansei engineering has always been a statistically and mathematically advanced methodology. Most types require good expert knowledge and a reasonable amount of experience to carry out the studies sufficiently. This has also been the major obstacle for a widespread application of Kansei engineering. In order to facilitate application some software packages have been developed in the recent years, most of them in Japan. There are two different types of software packages available: User consoles and data collection and analysis tools. User consoles are software programs that calculate and propose a product design based on the users' subjective preferences (Kanseis). However, such software requires a database that quantifies the connections between Kanseis and the combination of product attributes. For building such databases, data collection and analysis tools can be used. This part of the paper demonstrates some of the tools. There are many more tools used in companies and universities, which might not be available to the public. User consolesSoftware
As described above, Kansei data collection and analysis is often complex and connected with statistical analysis. Depending on which synthesis method is used, different computer software is used. Kansei Engineering Software (KESo) uses QT1 for linear analysis. The concept of Kansei Engineering Software (KESo) Linköping University in Sweden. The software generates online questionnaires for collection of Kansei raw-data Another software package (Kn6) was developed at the Polytechnic University of Valencia in Spain. Both software packages improve the collection and evaluation of Kansei data. In this way even users with no specialist competence in advanced statistics can use Kansei engineering.See also
*References
* Akao, Y., History of Quality Function Deployment in Japan. International Academy for Quality Books Series. Vol. 3. 1990: Hansa Publisher. * Baumgarten, A.G., Aesthetica. 1961, Hildesheim: Georg Olms Verlagsbuchhandlung. * ENGAGE, European Project on Engineering Emotional Design Report of the State of the Art- Round 1. 2005: Valencia. * Green, E.P. and V. Rao, Conjoint Measurement for Quantifying Judgemental data. Journal of Marketing Research, 1971: p. 61-68. * Grimsaeth Kjetil, “Kansei Engineering Linking Emotions and product features”, 2005, Norwegian University of Science and Technology. * Hirata Ricardo, Nagamachi Mitsuo, Ishihara Shigekazu, Satisfying Emotional Needs of the Beer Consumer through Kansei Engineering (Case Study with Hiroshima International University Students), 7th International QMOD Conference 2004, University of Linköping and ITESM, Monterrey, NL, pp. 219–227, México. * Hirata Ricardo, Nagamachi Mitsuo, Ishihara Shigekazu, Nishino Tatsuo,Translation of customer Kansei and emotional needs into products, 2nd International Conference on Applied Human Factors and Ergonomics (AHFEI) 2008, Las Vegas, USA. * Imamura, K., et al., An Application of Virtual Kansei Engineering to Kitchen Design, in Kansei Engineering 1, M. Nagamachi, Editor. 1997, Kaibundo Publishing Co., Ltd.: Kure. p. 63-68. * Kano, N., N. Seraku, and F. Takahashi, Attractive quality and must be quality, in Quality. 1984. p. 39-44. * Kant, I., Kritik av det rena förnuftet. 2004, Stockholm: Thales. * Küller, R., Semantisk Miljö Beskrivning (SMB). 1975, Stockholm: Psykologiförlaget AB Liber Tryck Stockholm. * Matsubara, Y. and M. Nagamachi, Kansei Virtual Reality Technology and Evaluation on Kitchen Design, in Manufacturing Agility and Hybrid Automation - 1, R.J. Koubek and W. Karwowski, Editors. 1996, IEA Press: Louisville, Kentucky, USA. p. 81-84.* * Mori, N., Rough set approach to product design solution for the purposed "Kansei". The Science of Design Bulletin of the Japanese Society of Kansei Engineering, 2002. 48(9): p. 85-94. * Nagamachi, M., Kansei Engineering. 1989, Tokyo: Kaibundo Publishing Co. Ltd. * Nagamachi Mitsuo, Kansei Kogaku no Ohanashi (Introduction to Kansei Engineering), Japan Standard Association, (in Japanese). * Nagamachi, Mitsuo, Kansei Engineering: A New ergonomic consumer oriented technology for product development, International Journal of Industrial Ergonomics 15, 3–11, 1995. * Nagamachi Mitsuo, Kansei Engineering: A new consumer oriented technology for product development, in W. Karwowski & W.S. Morris (editors), The Occupational Ergonomics Handbook, pp. 1835–1848, 1999, CRC Press LLC, USA. * Nagamachi Mitsuo, Kansei Engineering, in N. Stanton & A. Hedge ''et al.'', (editors), Handbook of Human Factors and Ergonomics Methods, pp. 83.1 – 83–5, 2004,CRC Press LLC, USA. * Nagamachi Mitsuo., ed., Nishino T., et al., Shohin Kaihatsu to Kansei (Desarrrollo de producto y Kansei), 2005, Kaibundo, Japan (in Japanese). * Nagamachi Mitsuo, Perspectives and New Trend of Kansei / Affective Engineering, 1st European Conference on Affective Design and Kansei Engineering & 10th QMOD Conference, 2007, University of Linkoping and Lund University, Helsingborg, Suecia. * Nagamachi, M., and Lokman, A.M., Kansei/Affective Engineering. 2011, CRC Press LLC, USA. * Nagamachi, M., and Lokman, A.M., Kansei Innovation, Practical Design Applications for Product and Service Development, 2015, CRC Press LLC, USA. * Lokman, A.M., and Nagamachi, M., Kansei Engineering; A Beginners Perspective, 2010, UPENA, Malaysia. * Lokman, A.M., and Nagamachi, M., Validation of Kansei Engineering Adoption In e-Commerce Web Design. Kansei Engineering International, Vol.9 No.1, 2009, JSKE, Japan. * Lokman, A.M., Design & Emotion: The Kansei Engineering Methodology, Malaysian Journal of Computing (MJOC), Vol1, pp 1–12. 2011, UPENA. * Nishino, T., Exercises on Kansei Engineering. 2001: Hiroshima International University. * Nishino, T., et al. Internet Kansei Engineering System with Basic Kansei Database and Genetic Algorithm. in TQM and Human Factors. 1999. Linköping, Sweden: Centre for Studies of Humans, Technology and Organization. * Osgood, C.E., G.J. Suci, and P.H. Tannenbaum, The measurement of meaning. 1957, Illinois: University of Illinois Press. 346. * Schütte, S., et al., Concepts, methods and tools in Kansei Engineering. Theoretical Issues in Ergonomics Science, 2004. 5: p. 214-232 * Schütte, R., Developing an Expert Program software for Kansei Engineering, in Institute of Technology, Linköping University. 2006, Linköping University: Linköping. * Shimizu, Y., et al., On-demand production system of apparel on basis of Kansei engineering. International Journal of Clothing Science and Technology, 2004. 16(1/2): p. 32-42. * Shimizu, Y. and T. Jindo, A fuzzy logic analysis method for evaluating human sensitivities. International Journal of Industrial Ergonomics, 1995. 15: p. 39-47.External links