Abstract
Embedded intelligence is radically changing the way designers conceptualize and develop technological artifacts. The use of smart materials to design products are uncovering new ways to interact with users so as to engage, entertain and inform them, coding new languages of communication. This study investigates how Smart Materials could support the monitoring of the user’s health condition in rehabilitation situations through an embedded input/output system, and how the occurring feedback could be perceived as unobtrusive, easy to understand and motivating. In this study, Flexers, an interactive finger splint is presented which includes adaptive and sensitive materials as a vehicle to achieve an intuitive interaction that promisingly shapes the occurring product experience with renewed engagement of the user. The results suggest that the use of smart materials combined with light based feedback could be used as a motivating tool for engaging the user in the rehabilitation activity.
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References
Jung, H., Stolterman, E.: Form and materiality in interaction design: a new approach to HCI. In: Proceedings of the 2011 annual conference extended abstracts on human factors in computing systems, 2011, pp. 399–408
Kuniavsky, M.: Smart Things: Ubiquitous Computing User Experience Design. Elsevier, Amsterdam (2010)
Peters, S.: Material Revolution: Sustainable and Multi-purpose Materials for Design and Architecture. Walter de Gruyter (2011)
Karana, E., Hekkert, P., Kandachar, P.: A tool for meaning driven materials selection. Mater. Des. 31(6), 2932–2941 (2010)
Karana, E., Pedgley, O., Rognoli, V.: Materials Experience: Fundamentals of Materials and Design. Butterworth-Heinemann (2013)
Poelman, W., Tempelman, E.: Organic interfaces. In: Digital Proceedings of the Tenth International Symposium on Tools and Methods of Competitive Engineering, TMCE 2014, Budapest, Hungary, 19–23 May 2014. Delft University of Technology (2014)
Spinelli, G., Micocci, M., Ajovalasit, M.: Behavioural Strategies of Older Adults in the Adoption of New Technology-Based Products: The Effects of Ageing and the Promising Application of Smart Materials for the Design of Future Products. Design for Health, Gower & Ashgate Publishing (in press)
Klack, L., Möllering, C., Ziefle, M., Schmitz-Rode, T.: Future care floor: a sensitive floor for movement monitoring and fall detection in home environments. In: Wireless Mobile Communication and Healthcare, pp. 211–218. Springer, New York (2011)
HSE: Musculoskeletal Disorders in Great Britain 2014. Retrieved 7 Nov 2014 from http://www.hse.gov.uk/Statistics/causdis/musculoskeletal/msd.pdf (2014)
NHS: Tendon injury recovery. Retrieved 15 Apr 2014 from http://www.nhs.uk/Conditions/tendonhand/Pages/Recovery.aspx (2015)
FDIs I. 9241-210: 2009: Ergonomics of Human System Interaction-part 210: Human-centred Design for Interactive Systems (formerly known as 13407). International Organization for Standardization (ISO), Switzerland (2009)
Ritter, A.: Smart Materials: In Architecture, Interior Architecture and Design. Springer, New York (2007)
Gandhi, M.V., Thompson, B.S.: Smart Materials and Structures. Springer, New York (1992)
Addington, M., Schodek, D.: Smart materials and technologies. Archit. Urbanism 5(3), 8–13 (2005)
Saul, G., Xu, C., Gross, M.D.: Interactive Paper Devices: End-User Design and Fabrication, pp. 205–212 (2010)
Kaihou, T., Wakita, A.: Electronic Origami with the Color-Changing Function, pp. 7–12 (2013)
Berglin, L.: Spookies: Combining Smart Materials and Information Technology in an Interactive Toy, pp. 17–23 (2005)
Coelho, M., Ishii, H., Maes, P.: Surflex: A Programmable Surface for the Design of Tangible Interfaces, pp. 3429–3434 (2008)
Kuswandi, B., Wicaksono, Y., Abdullah, A., Heng, L.Y., Ahmad, M.: Smart packaging: sensors for monitoring of food quality and safety. Sens. Instrum. Food Qual. Saf. 5(3–4), 137–146 (2011)
Minuto, A., Nijholt, A.: Growing Grass: A Smart Material Interactive Display, Design and Construction History, p. 7 (2012)
Zichermann, G., Cunningham, C.: Gamification by Design, p. xiv. O’Reilly Media, Sebastopol, Calif (2011)
Pereira, P., Duarte, E., Rebelo, F., Noriega, P.: Design, User Experience, and Usability. User Experience Design for Diverse Interaction Platforms and Environments, pp. 742–753. Springer, Cham (2014)
Kapp, K.: The Gamification of Learning and Instruction. Pfeiffer, San Francisco, CA (2012)
Banks, H.T., Smith, R.C., Wang, Y.: Smart Material Structures: Modeling, Estimation and Control. Wiley, New York (1996)
Culshaw, B., de Vries, M.: Smart structures and materials. Opt. Eng. 36(2), 616 (1997)
Srinivasan, A.V., McFarland, D.M.: Smart Structures: Analysis and Design. Cambridge University Press, Cambridge (2001)
Acknowledgments
This research study has been supported by the EU-funded FP7 collaborative research project Light.Touch.Matters (LTM), under agreement no. 310311.
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Ajovalasit, M., Micocci, M., Adam, R. (2016). Embedding Smart Materials into Products to Motivate the User: Flexers, a Smarter Approach to Finger Splinting. In: Rebelo, F., Soares, M. (eds) Advances in Ergonomics in Design. Advances in Intelligent Systems and Computing, vol 485. Springer, Cham. https://doi.org/10.1007/978-3-319-41983-1_12
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DOI: https://doi.org/10.1007/978-3-319-41983-1_12
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