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Prototyping a tangible tool for design: Multimedia e-paper sticky notes

Published online by Cambridge University Press:  17 June 2009

Maribeth Back
Affiliation:
FX Palo Alto Laboratory, Palo Alto, California, USA
Takashi Matsumoto
Affiliation:
FX Palo Alto Laboratory, Palo Alto, California, USA
Anthony Dunnigan
Affiliation:
FX Palo Alto Laboratory, Palo Alto, California, USA

Abstract

Modern design embraces digital augmentation, especially in the interplay of digital media content and the physical dispersion and handling of information. Based on the observation that small paper memos with sticky backs (such as Post-Its™) are a powerful and frequently used design tool, we have created Post-Bits, a new interface device with a physical embodiment that can be handled as naturally as paper sticky notes by designers, yet add digital information affordances as well. A Post-Bit is a design prototype of a small electronic paper device for handling multimedia content, with interaction control and display in one thin flexible sheet. Tangible properties of paper such as flipping, flexing, scattering, and rubbing are mapped to controlling aspects of the multimedia content such as scrubbing, sorting, or up- or downloading dynamic media (images, video, text). In this paper we discuss both the design process involved in building a prototype of a tangible interface using new technologies, and how the use of Post-Bits as a tangible design tool can impact two common design tasks: design ideation or brainstorming, and storyboarding for interactive systems or devices.

Type
Research Article
Copyright
Copyright © Cambridge University Press 2009

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References

REFERENCES

Bellotti, V., & Rogers, Y. (1997). From Web press to Web pressure: multimedia representations and multimedia publishing. Proc. Conf. Human Factors in Computing Systems, pp. 279286.CrossRefGoogle Scholar
Elliot, K., Neustaedter, C., & Greenberg, S. (2007). Sticky Spots: using location to embed technology in the social practices of the home. Proc. 1st Int. Conf. Tangible and Embedded Interaction, pp. 7986.CrossRefGoogle Scholar
Gill, S. (2003). Developing Information Appliance Design Tools for Designers; Personal and Ubiquitous Computing, Vol. 7, pp. 159162. London: Springer–Verlag.Google Scholar
Gorbet, M.G., Orth, M., & Ishii, H. (1998). Triangles: tangible interface for manipulation and exploration of digital information topography. Proc. CHI ’98, pp. 4956.CrossRefGoogle Scholar
Halasz, F., Moran, T., & Trigg, R. (1987). Notecards in a nutshell. Proc. SIGCHI/GI Conf. Human Factors in Computing System and Graphics Interface, pp. 4552.CrossRefGoogle Scholar
Harrison, B.L., Fishkin, K., Gujar, A., Mochon, C., & Want, R. (1998). The design and use of squeezable computers: an exploration of manipulative user interfaces. Proc. CHI ’98, pp. 1823.Google Scholar
Ichimura, S., Nelson, L., & Pedersen, E. (2000). Card Gear: a presentation system manipulated with paper cards. Proc. Interaction 2000, Information Processing Society of Japan, pp. 1724.Google Scholar
Ikeda, Y., Sato, K., & Kimura, A. (2003). TOOL DEVICE: handy haptic feedback devices imitating every day tools. Proc. HCI Int. ’03, pp. 661665.Google Scholar
Ishii, H., & Ullmer, B. (1997). Tangible bits: towards seamless interfaces between people, bits and atoms. Proc. CHI ’97, pp. 2227.CrossRefGoogle Scholar
Lamping, J., & Rao, R. (1996). The hyperbolic browser: a focus + context technique for visualizing large hierarchies. Journal of Visual Languages & Computing 7 (1), 3355.CrossRefGoogle Scholar
Ludolph, F., Norman, G., & Spiegel, J. (1998). Macintosh OS X Dock system. US Patent 6,133,898 to Apple Computer, Inc., Cupertino, CA.Google Scholar
MacIntyre, B., Mynatt, E.D., Voida, S., Hansen, K.M., Tullio, J., & Corso, G.M. (2001). Support for multitasking and background awareness using interactive peripheral displays. Proc. ACM UIST ’01, pp. 4150.CrossRefGoogle Scholar
Merrill, D., Kalanithi, J., & Maes, P. (2007). Siftables: towards sensor network user interfaces. Proc. 1st Int. Conf. Tangible and Embedded Interaction, pp. 7578.CrossRefGoogle Scholar
Mistry, P., & Maes, P. (2008). Intelligent sticky notes that can be searched, located, and can send reminders and messages. Proc. Intelligent User Interfaces ’08, pp. 425426.CrossRefGoogle Scholar
Moran, T.P., Saund, E., Melle, W.V., Gujar, A.U., Fishkin, K.P., & Harrison, B.L. (1999). Design and technology for collaborage: collaborative collages of information on physical walls. Proc. UIST ’99, pp. 197206.CrossRefGoogle Scholar
Nelson, L., Ichimura, S., Pedersen, E., & Adams, L. (1999). Palette: a paper interface for giving presentations. Proc. CHI ’99, pp. 354361.CrossRefGoogle Scholar
Orth, M., & Weinberg, G. (2001). Music Shapers. Accessed November 12, 2008, at http://www.media.mit.edu/hyperins/projects/shapers.htmlGoogle Scholar
Paradiso, J., & Hsiao, K. (1999). Swept-frequency, magnetically-coupled resonant tags for realtime, continuous, multiparameter control. Proc. CHI ’99 Extended Abstracts, pp. 212213.CrossRefGoogle Scholar
Rekimoto, J. (1997). Pick-and-drop: a direct manipulation technique for multiple computer environments, Proc. UIST ’97, pp. 3139.CrossRefGoogle Scholar
Schwesig, C., Poupyrev, I., & Mori, E. (2003). Gummi: user interface for deformable computers. Proc. CHI ’03, pp. 954955.CrossRefGoogle Scholar
Shipman, F., Marshall, C., & Moran, T. (1995). Finding and using implicit structure in human-organized spatial layouts of information. Proc. SIGCHI, pp. 346353.CrossRefGoogle Scholar
Ueda, J., Matsumoto, T., & Okude, N. (2004). Cubic display device “Z-agon.” Adjunct Proc. Ubicomp ’04. Accessed at http://www.z-agon.comGoogle Scholar
Want, R., Fishkin, K., Gujar, A., & Harrison, B. (1999). Bridging physical and virtual worlds with electronic tags. Proc. CHI ’99, pp. 370377.CrossRefGoogle Scholar