Yura Tamai
ABSTRACT
Persistence of Vision (POV) display uses a technique that presents an after-image that occurs when rhythmic blinking LEDs are moved swiftly. It is a cost-effective and simple method used to turn a large surface into a display. In addition, a characteristic visual expression, such as one floating in the air, can be produced. This technique is widely used because of its advantages, however, it has the limitation of poor interactivity. In this study, a system in which a smartphone can be used as a POV display by mounting a rotation mechanism and installing original applications is suggested. Furthermore, examples of the application and the possibility of interaction methods using this system are presented, including the concept, implementation, experimental results, and implications.
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- Yutaka Kunita, Naoko Ogawa, Atsushi Sakuma, Masahiko Inami, Taro Maeda, and Susumu Tachi. 2001. Immersive Autostereoscopic Display for Mutual Telexistence: TWISTER I (Telexistence Wide-angle Immersive STEReoscope model I). In Proceedings of the Virtual Reality 2001 Conference (VR'01) . pp. 31-36.Google Scholar
Cross Ref
- Koji Tsukada and Toshiyuki Masui. 2006. PhantomParasol: a parasol-type display transitioning from ambient to detailed. Adjunct Proceedings of Pervasive 2006. pp. 97-101.Google Scholar
- Azusa Kadomura, Yoko Ichioka, Koji Tsukada, Jun Rekimoto, and Itiro Siio. 2014. AwareCycle: Application for Sports Visualization Using an Afterimage Display Attached to the Wheel of a Bicycle. Human-Computer Interaction. Applications and Services(HCII '14). vol 8512. pp. 256-264.Google ScholarCross Ref
- Norihisa Hashimoto, Yoshitsugu Yanagi, and Yoshiharu Deguchi. 2012. Panorama Ball Vision : A Small Spherical Display with Rotary LED Arrays. In Transactions of the Virtual Reality Society of Japan (VRSJ'12), Vol. 17. Issue 3, pp. 151-160.Google Scholar
- Wataru Yamada, Kazuhiro Yamada, Hiroyuki Manabe, and Daizo Ikeda. 2017. ISphere: Self-Luminous Spherical Drone Display. In Proceedings of the 30th Annual ACM Symposium on User Interface Software and Technology (UIST '17). pp. 635–643.Google ScholarDigital Library
- Takashi Fukaya, Toshio Iwai, and Yuko Yamanouchi. 2006. Morphovision. In ACM SIGGRAPH 2006 Emerging technologies (SIGGRAPH '06). pp. 22–es.Google Scholar
- Takatoshi Yoshida, Yoshihiro Watanabe, and Masatoshi Ishikawa. 2016. Phyxel: Realistic Display of Shape and Appearance using Physical Objects with High-speed Pixelated Lighting. In Proceedings of the 29th Annual Symposium on User Interface Software and Technology (UIST '16). pp. 453–460.Google ScholarDigital Library
- Kunihiro Kato and Homei Miyashita. 2015. ExtensionSticker: A Proposal for a Striped Pattern Sticker to Extend Touch Interfaces and its Assessment. In Proceedings of the 33rd Annual ACM Conference on Human Factors in Computing Systems (CHI '15). pp. 1851–1854.Google ScholarDigital Library
- Hamed Ketabdar, Mehran Roshandel, and Kamer Ali Yüksel. 2010. Towards using embedded magnetic field sensor for around mobile device 3D interaction. In Proceedings of the 12th international conference on Human computer interaction with mobile devices and services (MobileHCI '10). pp. 153–156.Google ScholarDigital Library
- Azusa Kadomura and Itiro Siio. 2015. MagNail: user interaction with smart device through magnet attached to fingernail. In Adjunct Proceedings of the 2015 ACM International Joint Conference on Pervasive and Ubiquitous Computing and Proceedings of the 2015 ACM International Symposium on Wearable Computers (UbiComp/ISWC'15 Adjunct). pp. 309–312.Google Scholar
- Jens Grubert, Eyal Ofek, Michel Pahud, Matthias Kranz, and Dieter Schmalstieg. 2016. GlassHands: Interaction Around Unmodified Mobile Devices Using Sunglasses. In Proceedings of the 2016 ACM International Conference on Interactive Surfaces and Spaces (ISS '16). pp. 215–224.Google ScholarDigital Library
- Chihiro Watanabe, Alvaro Cassinelli, Yoshihiro Watanabe, and Masatoshi Ishikawa. 2014. Generic method for crafting deformable interfaces to physically augment smartphones. In CHI '14 Extended Abstracts on Human Factors in Computing Systems (CHI EA '14). pp. 1309–1314.Google ScholarDigital Library
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