Abstract
The design of services has become an important issue discussed in various industries. For the design of attractive and sustainable services, it is important to satisfy the requirements of various stakeholders simultaneously. To evaluate the fulfillment of them in a quantitative manner, the process simulation of a service would be an effective approach. However, the method to develop a simulation model to evaluate a service with various evaluation criteria has not been proposed. In this study, the authors propose the evaluation framework and the service process model to describe the influence of a service to various stakeholders and suggest the simulation method based on it.
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References
Alonso-Rasgado T., Thompson G., Elfstrom B. O. (2004) The design of functional (total care) products. Journal of Engineering Design 5(6): 515–540
Charnes A., Cooper W. (1961) Management models and industrial applications of linear programming, Vol. 1. John Wiley & Sons, New York
Cooper, A. (1999). The inmates are running the asylum: Why high-tech products drive us crazy and how to restore the sanity. Sams.
FIPS PUB 183. (1984). Integration definition for function modeling (IDEF0), Federal information processing standards. United States National Institute of Standards and Technology (NIST), Computer Systems Laboratory, Gaithersburg.
Fonseca, C. M., & Fleming, P. J. (1993). Genetic algorithms for multiobjective optimization, formulation, discussion and generalization. In Proceedings of the fifth international conference on genetic algorithms (pp. 416–423).
Karpowitz D. J., Cox J. J., Humpherys J. C., Warnick S. C. (2008) A dynamic workflow framework for mass customization using web service and autonomous agent techniques. Journal of Intelligent Manufacturing 19(5): 537–552
Kimita, K., Yoshimitsu, Y., Shimomura, Y., & Arai, T. (2008), A customers’ value model for sustainable service design. In Proceedings of the 15th CIRP life cycle engineering seminar, CD-ROM.
Lee M., Yoon H., Shin H., Lee D. G. (2009) Intelligent dynamic workflow support for a ubiquitous Web service-based manufacturing environment. Journal of Intelligent Manufacturing 20(3): 295–302
Matzen, D., & McAloone, T. C. (2006). A tool for conceptualizing in PSS development. In Proceedings of 17th. Symposium on design for X, October 2006 (pp. 131–140). Neukirchen.
Mont O. K. (2002) Clarifying the concept of product-service system. Journal of Cleaner Production 10(3): 237–245
Morelli N. (2002) Designing product/service systems: A methodological exploration. Design Issues 18(3): 3–17
Murata T. (1989) Petri nets: Properties, analysis and application. Proceedings of the IEEE 77(4): 541–580
Ramaswamy R. (1996) Design and management of service processes. Addison-Wesley, Reading, MA
Sakao T., Shimomura Y. (2007) Service engineering: A novel engineering discipline for producers to increase value combining service and product. Journal of Cleaner Production 15(6): 590–604
Sakao T., Shimomura Y., Sundin E., Comstock M. (2009) Modeling design objects in CAD system for service/product engineering. Computer-Aided Design 41(3): 197–213
Shimomura Y., Tomiyama T. (2005) Service modeling for service engineering. IFIP International Federation for Information Processing 167: 31–38
Shimomura, Y., Sakao, T., Sundin, E., & Lindahl, M. (2007). A design process model and a computer tool for service design. In Proceedings of the 12th design for manufacturing and the life cycle conference—DFMLC2007-. The American Society for Mechanical Engineering (ASME), CD-ROM.
Shimomura Y., Hara T., Arai T. (2009) A unified representation scheme for effective PSS development. CIRP Annals—Manufacturing Technology 58(1): 379–382
Shostack G. L. (1984) Designing services that deliver. Harvard Business Review 62(1): 133–139
Spohrer J., Maglio P. P. (2008) The emergence of service science: Toward systematic service innovations to accelerate co-creation of value. Production and Operations Management 17(3): 1–9
Stephen, A. W. (2004). Introduction to BPMN. BPTrends.
Sundin, E., Lindahl, M., & Larsson, H. (2010). Environmental and economic benefits of industrial product/service systems. In Proceedings of CIRP industrial product/service systems (IPS2) (pp. 91–98).
Tateyama, T., Kawata, S., & Shimomura, Y. (2007). Development of scene transition net(STN) GUI simulator for discrete-continuous hybrid systems. In Proceedings of the 7th Japan Korea workshop on CAD/CAM—design engineering workshop-(pp. 82–87). Tokyo.
Tukker A. (2004) Eight types of product-service system: Eight ways to sustainability? experiences from suspronet. Business Strategy and the Environment 13(4): 246–260
Tukker, A. & Tischner, U. (2006). New business for old Europe. Greenleaf Publishing.
Watanabe, K., Kimita, K., Akasaka, F., & Shimomura, Y. (2009). Requirement analysis and negotiation for feasible service development. In Proceedings of the 35th design automation conference—DAC2009-. The American Society for Mechanical Engineering (ASME), CD-ROM.
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Watanabe, K., Mikoshiba, S., Tateyama, T. et al. Service process simulation for integrated service evaluation. J Intell Manuf 23, 1379–1388 (2012). https://doi.org/10.1007/s10845-010-0497-x
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DOI: https://doi.org/10.1007/s10845-010-0497-x