多指觸控顯示器之實體互動

Neng-Hao Yu; 余能豪

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/10175

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	洪一平(Yi-Ping Hung)
dc.contributor.author	Neng-Hao Yu	en
dc.contributor.author	余能豪	zh_TW
dc.date.accessioned	2021-05-20T21:07:30Z	-
dc.date.available	2011-07-06
dc.date.available	2021-05-20T21:07:30Z	-
dc.date.copyright	2011-07-06
dc.date.issued	2011
dc.date.submitted	2011-06-18
dc.identifier.citation	[1] Bamboo pen & touch http://www.wacom.com/bamboo/bamboo_pen_touch.php [2] Banzi M., Getting Started with Arduino. OReilly, 2009. [3] Barrett, G. and Omote, R. Projected-Capacitive Touch Technology. Information Display, March 2010/vol. 26, NO. 3, Society for Information Display, 17-18. [4] Baudisch, P. and Chu, G. Back-of-device interaction allows creating very small touch devices. In Proc. CHI 2009. 1923-1932 [5] Baudisch, P., Becker, T., and Rudeck, F. Lumino: tangible blocks for tabletop computers based on glass fiber bundles. In Proc. of CHI 2010, 1165-1174. [6] Block, F., Haller, M., Gellersen, H., Gutwin, C., and Billinghurst, M. VoodooSketch -- extending interactive surfaces with adaptable interface palettes. In Proc. of TEI 2008, 55-58. [7] Brave, S. and Dahley, A. inTouch: A Medium for Haptic Interpersonal Communication. In Proc. of CHI’97 Extended Abstracts, ACM, 363 – 364. [8] Brave, S., Ishii, H., and Dahley, A. Tangible interfaces for remote collaboration and communication. In Proc. of CSCW’98, ACM, 169 – 178. [9] Brewster, S. and Chohan, F., and Brown, L. Tactile Feedback for Mobile Interactions, Ext. Abstracts CHI 2007, 159-162. [10] Camarata, K., Do, E.Y.L., Johnson, B.R., and Gross, M.D. Navigational blocks: navigating information space with tangible media. In Proc. of IUI’02, ACM, 31 – 38. [11] Chang, A., Resner, B., Koerner, B., Wang, X., and Ishii, H. LumiTouch: An emotional communication device. In Proc. of CHI’01 Extended Abstracts, ACM, 313 – 314. [12] Chang, A.Y., Lee, W.C., and Lee, W.Y. 2010. Touchscreen Stylus. U.S. Patent US 2010/0053120 A1. Mar. 2010. [13] Chung, H., Lee, C.J., and Selker, T. Lover’s cups: Drinking interfaces as new communication channels. In Proc. of CHI’06 Extended Abstracts, ACM, 375 – 380. [14] Dahley, A., Wisneski, C., and Ishii, H. Water lamp and pinwheels: ambient projection of digital information into architectural space. In Proc. of CHI’98, ACM, 269 – 270. [15] Dietz, P., Leigh, D. 2001. DiamondTouch: a multi-user touch technology. UIST ‘01: In Proceedings of the 14th Annual ACM Symposium on User Interface Software and Technology. 219-226. [16] Fallahkhair S., Pemberton L., and Masthoff J., A dual device scenario for informal language learning: Interactive television meets the mobile phone, Advanced Learning Technologies, IEEE International Conference on, vol. 0, pp. 16–20, 2004. [17] Fiala, M. ARTag, a fiducial marker system using digital techniques. In Proc. of IEEE CVPR 2005, 590-596 vol. 2. [18] Fitzmaurice G. W., Ishii H., and Buxton W., Bricks: Laying the foundations for graspable user interfaces, in Proceedings of CHI95, pp. 442–449, NY: ACM, 1995. [19] Forlines C., Esenther A., Shen C., Wigdor D., and Ryall K., Multi-user, multi-display interaction with a single-user, single-display geospatial application, UIST, pp. 273–276, 2006. [20] Fukumoto, M. and Sugimura, T. Active Click: Tactile Feedback for Touch Panels, Ext. Abstracts CHI 2001, 121-122. [21] GestureWorks http://gestureworks.com/ [22] Girouard, A. Solovey E. T., Hirshfield L. M., Ecott S., Shaer O., and Jacob R. J. K., Smart blocks: A tangible mathematical manipulative, in Proceedings of TEI07, pp. 183–186, NY: ACM, 2007. [23] Glaeser T., Google earthwalk with arduino at berlin design mai 2007. [24] Gohlke, K., Hlatky, M., Helse, S. and Loviscach, J. FlexiKnobs: bridging the gap between mouse interaction and hardware controllers. In Proc. TEI 2010, 241 – 244 [25] Google, “Liquid galaxy live demo at ted,” Lecture Notes in Computer Science, Springer, 2010. [26] Greenberg, S. and Buxton, B. Usability evaluation considered harmful (some of the time). In Proc. of CHI 2008, 111-120. [27] Guo, C. and Sharlin, E. Exploring the use of tangible user interfaces for human-robot interaction: a comparative study. In Proc. of CHI 2008, 121-130. [28] Hermitage Nouso: Tactile+Plus. http://game.watch.impress.co.jp/docs/series/ggl/20101102_404249.html. . [29] Hinckley, K., Yatani, K., Pahud, M., Coddington, N., Rodenhouse, J., Wilson, A., Benko, H., and Buxton, B. Pen + Touch = New Tools. In Proc. of UIST 2010, 27-36. [30] Hiraoka, S., Miyamoto, I. and Tomimatsu, K. Behind Touch, a Text Input Method for Mobile Phones by The Back and Tactile Sense Interface. Information Processing Society of Japan, Interaction 2003,131-138. [31] Hu, T. T., Chia, Y. W., Chan, L. W., Hung, Y. P., & Hsu, J. (2008). i-m-Top: An interactive multi-resolution tabletop system accommodating to multi-resolution human vision. 3rd IEEE International Workshop on Horizontal Interactive Human Computer Systems, 2008. TABLETOP 2008, 177-180. [32] IAR Embedded Workbench http://www.iar.com [33] Ishii, H. and Ullmer, B. Tangible bits: towards seamless interfaces between people, bits and atoms. In Proc. of CHI’97. ACM, 234 – 241. [34] Ishii, H. The tangible user interface and its evolution. Communications of the ACM 2008, 32-36. [35] Ishii, H., Tangible bits: beyond pixels, In Proc. of TEI 2008, xv-xxv. [36] Ishii, H., Wisneski, C., Brave, S., Dahley, A., Gorbet, M., Ullmer, B., and Yarin, P. ambientROOM: integrating ambient media with architectural space. In Proc. of CHI’98, ACM, 173 – 174. [37] Iwata, H., Yano, H., Nakaizumi, F., and Kawamura, R. Project FEELEX: adding haptic surface to graphics. In Proc. of SIGGRAPH’01, ACM, 469 – 476. [38] Izadi, S., Hodges, S., Butler, A., Rrustemi, A., and Buxton, B. ThinSight: integrated optical multi-touch sensing through thin form-factor displays. In Proc. of EDT 2007, Art. NO. 6. [39] Jacob R. J. K., Ishii H., Pangaro G., and Patten J., A tangible interface for organizing information using a grid, in Proceedings of CHI ’02, pp. 339–346, NY: ACM, 2002. [40] Jorda, S., Geiger, G., Alonso, M., and Kaltenbrunner, M. The reacTable: exploring the synergy between live music performance and tabletop tangible interfaces. In Proc. of TEI 2007, 139–146. [41] Jorda, S., Julia, F.C., and Gallardo, D. Interactive surfaces and tangibles. XRDS: Crossroads, The ACM Magazine for Students 2010, vol. 16 (4), 21-28. [42] Jul S. and Furnas G. W., Navigation in electronic worlds - workshop report, SIGCHI Bulletin, vol. 29, pp. 44–49, 1997. [43] Kalanithi, J.J. and Bove, V. Connectibles: tangible social networks. In Proc. of TEI’08, ACM, 199 – 206. [44] Karlson, A., Bederson, B., Contreras-Vidal, J. (2006) Understanding Single-Handed Mobile Device Interaction. Tech Report HCIL-2006-02, Computer Science Dept., University of Maryland [45] Kato, J., Sakamoto, D., Inami, M., and Igarashi, T. Multi-touch interface for controlling multiple mobile robots. In Proc. of CHI’09. ACM, 3443 – 3448. [46] Kim S. gook, Arif S. N., woon Kim J., and woo Lee C., Multi-touch tabletop interface technique for HCI. [47] Kirk D. S., Sellen A., Taylor S., Villar N., and Izadi S., Putting the physical into the digital: Issues in designing hybrid interactive surfaces, in Proceedings of HCI 2009, 2009. [48] Klemmer, R.S., Li, J., Lin, J., and Landay J.A. Papier-Mache: toolkit support for tangible input. In Proc. CHI 2004, 399-406 [49] Kojima, M., Sugimoto, M., Nakamura, A., Tomita, M., Nii, H., and Inami, M. Augmented coliseum: an augmented game environment with small vehicles. Horizontal Interactive Human-Computer Systems’06. IEEE TableTop’06. [50] Koleva B., Benford S., Ng K. H., and Rodden T., A Framework for Tangible User Interfaces, Physical Interaction, Workshop on Real World User Interfaces, Mobile HCI Conference 2003, Udine, Italy, 2003. [51] Koskinen, E., Kaaresoja, T. and Laitinen, P. Feel-good touch: finding the most pleasant tactile feedback for a mobile touch screen button. In Proc. ICMI 2008. [52] Kuzuoka, H. and Greenberg, S. Mediating awareness and communication through digital but physical surrogates. In Proc. of CHI’99 Extended Abstracts, ACM, 11 – 12. [53] Laehyun Kim S. P. M. H., Cho Hyunchul, A tangible user interface with multimodal feedback, Lecture Notes in Computer Science, Springer, 2007. [54] Li, K., Baudisch, P. and Hinckley, K. BlindSight: eyes-free access to mobile phones. In Proc. CHI 2008, 1389-1398. [55] Liu, Y.C. and Tseng, H.H. 2009. Stylus and Electronic Device. U.S. Patent 2009/0167727 A1. Jul. 2009. [56] MacKenzie, I.S., Soukoreff, R.W. Text entry for mobile computing: Models and methods, theory and practice. Human-Computer Interaction 17 (2). Lawrence Erlbaum, 2002, 147-198 [57] Maher M. L. and Kim M. J., Studying designers using a tabletop system for 3d design with a focus on the impact on spatial cognition, Horizontal Interactive Human-Computer Systems, International Workshop on, vol. 0, pp. 105–112, 2006. [58] Mangen, A. and Velay J.L. Digitizing Literacy: Reflections on the Haptics of Writing. In Journal of Advances in Haptics (2010), 385-401. [59] Martinussen E. S. and Arnall T., Designing with RFID, in Proceedings of TEI 2009, pp. 343–350, NY: ACM, 2009. [60] Michon P.-E. and Denis M., When and why are visual landmarks used in giving directions? in COSIT 2001: Proceedings of the International Conference on Spatial Information Theory. London, UK: Springer-Verlag, 2001, pp. 292–305. [61] Micire, M., Desai, M., Courtemanche, A., Tsui, K. M., and Yanco, H. A. Analysis of natural gestures for controlling robot teams on multi-touch tabletop surfaces. In Proc. of ITS’09. ACM, 41 – 48. [62] Minami, M., Fukuju, Y., Hirasawa, K., Yokoyama, S., Mizumachi, M., Morikawa, H., and Aoyama, T. Dolphin: A practical approach for implementing a fully distributed indoor ultrasonic positioning system. In Proc. of UBICOMP 2004, 347-356. [63] Nashel, A. and Razzaque, S. Tactile Virtual Buttons for Mobile Devices, Ext. Abstracts CHI 2003, 854-855. [64] NET.2971 - The Microsoft Surface domino tag. http://www.xs4all.nl/~wrb/Main/Index.htm. [65] Orit Shaer and Eva Hornecker. Tangible User Interfaces: Past, Present, and Future Directions. In Foundations and Trends in Human-Computer Interaction 3,1 (2010) 1-138 [66] Pangaro, G., Maynes-Aminzade, D., and Ishii, H. The actuated workbench: computer-controlled actuation in tabletop tangible interfaces. In Proc. of UIST’02, ACM, 181 – 190. [67] Patten, J. and Ishii, H. Mechanical constraints as computational constraints in tabletop tangible interfaces. In Proc. of CHI’07, ACM, 809 – 818. [68] Patten, J., Ishii, H., and Recht, B. Audiopad: a tag-based interface for musical performance. In Proc. of NIME 2002, 1-6. [69] Patten, J., Ishii, H., Hines, J., and Pangaro, G. Sensetable: A Wireless Object Tracking Platform for Tangible User Interfaces. In Proc. of CHI 2001, 253-260. [70] Pedersen, E.W. and Hornbak, Kasper. Tangible Bots: Interaction with Active Tangibles in Tabletop Interfaces. To appear in Proc. of CHI’11. [71] Potter, R., Weldon, L. and Shneiderman, B. Improving the accuracy of touch screens: an experimental evaluation of three strategies. In Proc. CHI 1988, 27-32. [72] Poupyrev I., Nashida T., and Okabe M., Actuation and tangible user interfaces: The Vaucanson duck, robots, and shape displays, in Proceedings of Tangible and Embedded interaction, TEI ’07, pp. 205–212, NY: ACM, 2007. [73] Poupyrev, I. Maruyama, S. and Rekimoto, J. Ambient touch: designing tactile interfaces for handheld devices. In Proc. UIST 2002, 51-60 [74] Poupyrew, I., Nashida, T., Maruyama, S., Rekimoto, J., and Yamaji, Y. Lumen: interactive visual and shape display for calm computing. In SIGGRAPH’04 Emerging technologies, ACM, 17. [75] QR code. http://www.qrcode.com/index-e.html. [76] Rekimoto, J., SmartSkin: an infrastructure for freehand manipulation on interactive surfaces. In ACM CHI 2002. [77] Rice, C.A., Cain, B.C., and Fawcett, K.J. Dependable coding for fiducial tags. In Proc. of UCS 2004, 155–163. [78] Rice, C.A., Harle, K.R., and Beresford, R.A. Analysing fundamental properties of marker-based vision system designs. In PerCom 2006, 453-471. [79] Rosenfeld, D., Zawadzki, M., Sudol, J., and Perlin, K. Physical Objects as Bidirectional User Interface Elements. In IEEE Computer Graphics and Applications’04, 44 – 49. [80] Senseg E-SenseR solution. http:// http://senseg.com/. [81] Shaer, O. and Hornecker, E. Tangible user interface: past, present and future directions. Foundations and Trends in Human-Computer Interaction: Vol. 3: No 1-2, pp 1 – 137. [82] Siek, K.A., Rogers, Y. and Connelly, K.H. Fat Finger Worries: How Older and Younger Users Physically Interact with PDAs. In Proc. INTERACT 2005, 267–280. [83] Strong, R. and Gaver, B. Feather, scent and shaker: Supporting simple intimacy. In Proc. of CSCW’96, ACM, 29 – 30. [84] Sugimoto, M. and Hiroki, K.. HybridTouch: an intuitive manipulation technique for PDAs using their front and rear surfaces. In Proc. MobileHCI 2006, 137-140. [85] Sun, X., Plocher, T. and Qu, W. An Empirical Study on the Smallest Comfortable Button/Icon Size on Touch Screen. Usability and Internationalization, Part I, HCII 2007, LNCS 4559, 615–621, 2007 [86] Ten One Design: Fling analog joystick. http://tenonedesign.com/fling [87] Texas Instruments MSP430 http://www.ti.com/ [88] TinyOS http://www.tinyos.net/. [89] Tom M. D. A., Referring to landmark or street information in route directions: What difference does it make?, vol. 2825, 2003, pp. 384–397. [90] Ullmer B., Ishii H., and Jacob R., Token+constraint systems for tangible interaction with digital information, ACM Transactions on Computer- Human Interaction, vol. 12, no. 1, pp. 81–118, 2005. [91] Ullmer, B., and Ishii, H. The metaDESK: models and prototypes for tangible user interfaces. In Proc. of UIST 1997, 223-232. [92] Ullmer, B., Ishii, H., and Glas, D. mediaBlocks: physical containers, transports, and controls for online media. In Proc. of SIGGRAPH 1998, 379-386. [93] Underkoffler, J., and Ishii, H. Urp: a luminous-tangible workbench for urban planning and design. In Proc. of CHI 1999, 386-393. [94] Vogel, D. and Baudisch, P. Shift: A Technique for Operating Pen-Based Interfaces Using Touch. In Proc. CHI 2007, 657-666. [95] Wagner H. S., Nusbaum and Goldin-Meadown S., Probing the mental representation of gesture: Is handwriting spatial?, Memory and Language, vol. 50, 2004. [96] Weiser, M. and Brown, J. Designing calm technology. Powergrid Journal, v 1.01, July 1996. [97] Weiss, M., Schwarz, F., Jakubowski, S., and Borchers, J. Madgets: actuating widgets on interactive tabletops. In Proc. of UIST’10, ACM, 293 – 302. [98] Weiss, M., Wagner, J., Jennings, R., Jansen, Y., Khoshabeh, R., Hollan, D.J., and Borchers, J. SLAP widgets: bridging the gap between virtual and physical controls on tabletops. In Proc. of CHI 2009, 3229-3234. [99] Wellner, P. Interacting with Paper on the DigitalDesk. Communications of the ACM 36, 7, (1993), 87-96 [100] Werner, J., Wettach, R., and Hornecker, E. United-pulse: Feeling your partners pulse. In Proc. of MobileHCI’08, ACM, 535 – 553. [101] Wilson, D.A. PlayAnywhere: a compact interactive tabletop projection-vision system. In Proc. of UIST 2005, 83-92. [102] Wobbrock, J.O., Myers, B.A. and Aung, H.H. The performance of hand postures in front- and back-of-device interaction for mobile computing. International Journal of Human-Computer Studies 2008, 857-875. [103] Xu, D., Read, C.J., Mazzone, E., and Brown, M. Designing and testing a tangible interface prototype. In Proc. of IDC 2007, 25-28. [104] Yanco, H. A. and Drury, J. L. Classifying Human-Robot Interaction: An Updated Taxonomy. In Proc. of the IEEE Conference on Systems, Man and Cybernetics, 2004. [105] Yu, N.H., Chan, L.W., Lau, S.Y., Tsai, S.S., Hsiao, I.C., Tsai, D.J., Cheng, L.P., Hsiao, F.I., Chen, M.Y., Huang, P. and Hung, Y.P. TUIC: Enabling Tangible Interaction on Capacitive Multi-touch Display. To appear in Proc. CHI 2011 [106] Zimmerman, D.T., Smith, R.J., Paradiso, A.J., Allport, D. and Gershenfeld, N. Applying electric field sensing to human-computer interfaces. In Proc. of CHI 1995, 280-287. [107] Zufferey G., Jermann P., Lucchi A., and Dillenbourg P., TinkerSheets: Using paper forms to control and visualize tangible simulations, in Proceedings of TEI09, pp. 377–384, NY: ACM, 2009.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/10175	-
dc.description.abstract	實體使用者介面之研究已發展二十多年,此一概念改變了使用鍵盤滑鼠操作電腦的生硬刻板印象。利用實體物件自然地連結數位資訊或執行對應的功能,提供使用者操作電腦的便利性與直覺性,藉由碰觸或移動物體時的觸覺回饋,更增強使用者與系統溝通的互動歷程。傳統上,開發實體使用者介面大多利用影像偵測技術來達成實物辨識之功能,因此需要複雜的硬體建置;本篇論文首先提出基於電容式觸控之實物偵測技術,簡化系統複雜度,讓普及的電容式面板,不需增改硬體便能支援實體使用者介面開發。我們提出三種 TUIC 標籤可附加在實體物件上以提供電容式觸控面板感測物件的能力;TUIC 標籤使用低成本的導電材質模擬手指觸控訊號,並將其在空間及時間上的排列做為物件編碼之方式。我們所發展的軟體讓電容式面板可分辨手指操作或是實體物件操作,結合多指觸控與實體使用者介面,我們提出兩種互動模型,分別呈現在大型互動桌及小型行動觸控裝置中。在互動桌上,我們開發一套支援多重顯示器之地圖導覽系統,使用者可使用象徵自己的人偶遊走在地圖上,並在前方顯示由人偶視角看到的街景圖,此系統讓街景視野與地圖方位有較好的連結,猶如使用者置身於虛擬世界中遊歷。在行動觸控裝置上,我們提出可延伸的實感觸控介面,藉由附加在裝置邊緣的延伸控制器,解決手指遮蔽畫面的問題,並提供觸覺回饋。更重要的是,此解決方案不需要電力且易於攜帶,有利於行動裝置之應用。除了使用實體物件做為輸入裝置,本篇論文並提出可動式實體互動介面,以螢幕本身的光訊號來傳送指令,讓 TUIC 標籤以光感元件接收,進而驅動實體物件產生對應的動作。我們將此技術運用在社交玩偶上,玩偶附有馬達可帶動舉手等動作,使用者可將代表不同好友的玩偶放置在 iPad 上,做為好友來電提示功能,當好友在社群網路傳送訊息或更新狀態時,便能以其動作提醒使用者,增加互動的趣味性。最後我們提出具有應用潛力的互動模式,供未來研究及商品開發做為參考方向。	zh_TW
dc.description.abstract	This dissertation presents technologies and interaction models that combine tangible interaction with multi-touch UI. It describes TUIC, a technology that enables tangible interaction on capacitive multi-touch displays without requiring any hardware modifications. TUIC simulates finger touches on capacitive displays, such as iPad, iPhone, and 3M’s multi-touch displays, using passive materials and active modulation circuits embedded inside tangible objects, and can be used with multi-touch gestures simultaneously. We demonstrate three TUIC approaches on iPads and 3M’s multi-touch displays: passive (2D), active (frequency), and hybrid. In addition, we have extended TUIC to support bidirectional tangible interaction. For object tracking, we can use TUIC tags. For communication, we embed photodiodes into objects, and transmit data to them by programmatically changing the screen’s brightness levels. We also present three novel tangible interaction models for tabletop-size and tablet-size multi-touch devices. First, our multi-display map touring system helps people use figurines to navigate through continuous panorama based on the street view, thus enhance better orientation perception and walkthrough experience. Second, Clip-on Gadgets solve the problem of fingers obscuring the screens and provide haptic feedback by extending the interaction area of multi-touch devices with unpowered physical controllers. Third, Social Toy uses motorized actuators to create ambient social awareness. Our contributions include providing low-cost and easy-to-build techniques to enable tangible interactions on off-the-shelf multi-touch devices, empowering developers to explore and create diverse TUI applications, and making TUI accessible to end users.	en
dc.description.provenance	Made available in DSpace on 2021-05-20T21:07:30Z (GMT). No. of bitstreams: 1 ntu-100-D96944013-1.pdf: 4061268 bytes, checksum: 3b97babca2789b99a777b0f16513bbe2 (MD5) Previous issue date: 2011	en
dc.description.tableofcontents	ABSTRACT ...................................................................................................................... i   LIST OF FIGURES ........................................................................................................ vii   LIST OF TABLES........................................................................................................... xi   CHAPTER 1 INTRODUCTION....................................................................................1 1.1   1.2   1.3 Background and motivation............................................................................1   Dissertation statement and overview ..............................................................2   Outline of the dissertation...............................................................................3 CHAPTER 2 RELATED WORK ..................................................................................5   2.1   Unidirectional TUIs ........................................................................................6   2.1.1   Tracking techniques ............................................................................14   2.2   Bidirectional TUIs ........................................................................................18   2.2.1   Actuated techniques ............................................................................21   2.3   Summary .......................................................................................................22   CHAPTER 3 TUIC: OBJECT SENSING AND TRACKING TECHNIQUES ON UNMODIFIED CAPACITIVE TOUCH PANELS ............................25   3.1   Introduction...................................................................................................25   3.2   Motivation.....................................................................................................26   3.3   TUIC tag design............................................................................................28 3.3.1   3.3.2   3.3.3 Tag design based on spatial domain....................................................28   Tag design based on time domain .......................................................29   Combining spatial and frequency tags ................................................31 3.4   Implementation .............................................................................................32   3.4.1   TUIC-2D .............................................................................................32 iii 3.4.2   TUIC-frequency ..................................................................................35   3.4.3   TUIC-hybrid........................................................................................38   3.5   Application examples ...................................................................................39 3.5.1   3.5.2   3.5.3 Chronicle of famous painters ..............................................................39   Slap-on calculator................................................................................40   Slap-on authentication key ..................................................................41 3.6   Discussion.....................................................................................................43   3.7   Summary .......................................................................................................46   CHAPTER 4 DESIGNING UNIDIRECTIONAL TANGIBLE INTERACTIONS FROM TABLETOP TO MOBILE DEVICE......................................47   4.1   Multi-display map touring system for interactive tabletop surfaces ............47 4.1.1   4.1.2   4.1.3   4.1.4 Motivation ...........................................................................................48   Survey of map touring systems ...........................................................50   System design......................................................................................52   Discussion ...........................................................................................53 4.2   Clip-on gadgets for portable multi-touch devices ........................................55 4.2.1   4.2.2   4.2.3   4.2.4 Motivation ...........................................................................................55   Survey of virtual controls....................................................................56   System design......................................................................................58   Discussion ...........................................................................................63 4.3   Summary .......................................................................................................64   CHAPTER 5 TUIC+: ENABLING BIDIRECTIONAL TANGIBLE INTERACTION ON CAPACITIVE MULTI-TOUCH DISPLAYS 65   5.1   Motivation.....................................................................................................65   5.2   TUIC+ tag design .........................................................................................66 iv 5.3   Application example: Social Toy .................................................................68 5.3.1   5.3.2   5.3.3 Scenario ...............................................................................................69   Active figurine as ambient display......................................................70   Social toy prototyping .........................................................................70 5.4   Discussion.....................................................................................................73   5.5   Summary .......................................................................................................74   CHAPTER 6 CONCLUSION AND FUTURE WORK .............................................77   6.1   Summary of the dissertation .........................................................................77   6.2   Future directions ...........................................................................................78   LIST OF REFERENCES.................................................................................................83
dc.language.iso	en
dc.title	多指觸控顯示器之實體互動	zh_TW
dc.title	Tangible Interaction Design on Multi-touch Display	en
dc.type	Thesis
dc.date.schoolyear	99-2
dc.description.degree	博士
dc.contributor.oralexamcommittee	蔡文祥(Wen-Hsiang Tsai),陳玲鈴(Lin-Lin Chen),王照明(Chao-Ming Wang),魏德樂(Der-lor Way),陳祝嵩(Chu-Song Chen),歐陽明(Ming Ouhyoung),許永真(Yung-Jen Hsu)
dc.subject.keyword	實體使用者介面,多指觸控,互動桌,觸覺回饋輸入裝置,可動式實體互動介面,電容式觸控技術,	zh_TW
dc.subject.keyword	tangible user interface,multi-touch,2D marker,frequency tag,physical interaction,interactive surface,tabletop,navigation,tactile input,bidirectional interfaces,active tangibles,capacitive sensing,	en
dc.relation.page	93
dc.rights.note	同意授權(全球公開)
dc.date.accepted	2011-06-21
dc.contributor.author-college	電機資訊學院	zh_TW
dc.contributor.author-dept	資訊網路與多媒體研究所	zh_TW
顯示於系所單位：	資訊網路與多媒體研究所

文件中的檔案：

檔案	大小	格式
ntu-100-1.pdf	3.97 MB	Adobe PDF	檢視/開啟

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。