Social Context Representation in Product-Service Systems with Internet of Things

DOI: 10.4236/jss.2015.37030   PDF   HTML   XML   3,531 Downloads   3,994 Views   Citations

Abstract

A Product-Service Systems (PSS) is composed of service and product element to provide values for relevant stakeholders. A typical service interaction involves providers and receivers, and respective values are provided in a social interaction. When service channel is supported by physical touchpoints, receivers will interact with products, which may interact with providers. Thus, in PSS, various kinds of interactions occur in diverse social contexts. These social contexts can be repre- sented using graphs where nodes represent stakeholders and product touchpoints and attributed edges represent the interaction. Interaction among products as well as that of human stakeholders and that of human and product touchpoint can be described using such a graph-based representation. In designing and operating PSS with internet of things, social context representations could be used in analyzing and comparing key aspects of social interaction types to retrieve similar cases to exploit related interaction design strategies and operation know-hows.

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Kim, Y. and Suzuki, K. (2015) Social Context Representation in Product-Service Systems with Internet of Things. Open Journal of Social Sciences, 3, 187-193. doi: 10.4236/jss.2015.37030.

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1] Kim, Y.S., Cho, C.K., Ko, Y.D. and Jee, H.S. (2011) E3 Value Concept for a New Design Paradigm. International Conference on Engineering Design (ICED), Copenhagen.
[2] Goedkoop, M.J., van Halen, C.J.G., te Riele, H.R.M. and Rommens, P.J.M. (1999) Product Service System, Ecological and Economic Basic. The Report No. 1999/36 Submitted to Ministerje van Volkshuisvesting, Ruimtelijke Ordening en Milieubeheer, Hague.
[3] Kim, Y.S. and Hong, Y.K. (2012) Interaction Model for Products and Services Using Affordance. Proceedings of ASME Computers and Information in Engineering Conference, Chicago. http://dx.doi.org/10.1115/detc2012-71110
[4] ISO 20282-1 (2006) Ease of Operation of Everyday Products, Part1: Design Requirements for Context of Use and User Characteristics. ISO.
[5] Kim, Y.S., Lee, S.W., Kim, J.H., Jeong, H., Lee, J.H. and Hong, Y.S. Product-Service Systems Design with Business Model Strategy Integrated: A Case Study of Urban Umbrella Rental Service System.
[6] Kim, Y.S., Do, S.H., Kim, J.H., Jeong, H., Lee, J.H. and Hong, Y.S. (2012) Product-Service Systems Design with Service Unit and Business Model Strategy: A Case Study of Make-Up Room Service. Design Engineering Workshop, Seoul.
[7] Belkins WEMO-SmartPlug. http://www.belkin.com/us/Products/home-automation/c/wemo-home-automation.
[8] Dawon, D.N.S. Power Manger-SmartPlug. http://www.powermanager.co.kr
[9] Lee, H.J., Kim, Y.S. and Park, S.H. (2014) Smart Plug Service Model and Business Models. Asia Design Engineering Workshop, Taipei.
[10] Donaldson, K., Ishii, K. and Sheppard, S. (2006) Customer Value Chain Analysis. Research in Engineering Design, 16.

  
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