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研究生:林龍飛
研究生(外文):Long-Fei Lin
論文名稱:為便攜顯示器上的手寫筆輸入設計動態約束
論文名稱(外文):Designing Dynamic Constraints for Facilitating Stylus Inputs On Portable Displays
指導教授:陳炳宇陳炳宇引用關係
指導教授(外文):Bing-Yu Chen
口試委員:梁容豪朱浩華余能豪
口試委員(外文):Rong-Hao LiangHao-Hua ZhuNeng-Hao Yu
口試日期:2016-05-24
學位類別:碩士
校院名稱:國立臺灣大學
系所名稱:資訊網路與多媒體研究所
學門:電算機學門
學類:網路學類
論文種類:學術論文
論文出版年:2016
畢業學年度:104
語文別:英文
論文頁數:37
中文關鍵詞:動態物理約束; 便攜式螢幕;觸控筆輸入
外文關鍵詞:dynamic physical constraintportable displaystylus input.
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本篇論文提出了兩種馬達陣列的系統的設計,DynaFrame 與 Dyn- aBase,其目的在於對觸控筆進行動態約束,以輔助或限制觸控筆在顯 示器上的筆劃輸入。DynaFrame 外形類似框架包圍在螢幕周圍,由機 器人手臂作為驅動,從而可以控制和約束觸控筆在屏幕上方的移動軌 跡,DynaFrame 的優點在於擁有近螢幕表面的三維空間運動能力,但 手臂在運動過程中會遮擋螢幕上面的內容。DynaBase 與 DynaFrame 類 似,由機械手臂驅動,位於螢幕下方,手臂末端綁定磁性轉軸,透過 磁性來操縱屏幕上方的動態約束,由於用戶會將畫筆放置在該約束上, 以此來控制觸控筆的輸入。DynaBase 基本不會遮擋螢幕的內容,但失 去了近螢幕表面的三維運動能力。
本文提出的兩種動態約束系統,其裝置外形體積符合可便攜的需 求。在儘量減少螢幕內容遮擋的前提下,能夠動態地輔助或限制使用 者觸控筆的互動。不同的約束方式-剛性約束以及柔性約束為用戶提 供了準確可靠且具有表現力的力反饋感受。
我們在這篇論文中,我們實作了兩種動態約束裝置,評估其技術細 節,并詳細描述了設計考量,基於兩者的不同硬體設計方式,以及約 束形態的不同,設計了相對應用場景。最終我們探討 DynaFrame 以及 DynaBase 未來可能的展望。


This work proposed two designs of actuator array system, DynaFrame and DynaBase, to realize dynamic physical constraints on portable displays for facilitating stylus input. DynaFrame is a frame-like device consists of a miniaturized robot arm surrounding the display, allowing for manipulating the stylus placed on the display surface in the near surface 3D volume. DynaBase is a basestation-like actuation platform consists of an robot arm controlling a magnetic shaft , which can manipulate a physical constraint placed on a portable display that user docked on it.
Both of dynamic constraint systems are portable, provide active force feedback as expressive and precise hard or soft constraints. The provided dynamic constraints therefore facilitate users performing stylus interactions without introducing significant occlusions on the portable display.
Furthermore, we implement the system and evaluate its technical features. In this paper, we describe the details of the design and implementations of the device, along with applications, technical evaluations, and future prospects.

[1] BryggUllmer,HiroshiIshii,andRobertJKJacob.Token+constraintsystemsfortan- gible interaction with digital information. ACM Transactions on Computer-Human Interaction (TOCHI), 12(1):81–118, 2005.
[2] Sean Follmer, Daniel Leithinger, Alex Olwal, Akimitsu Hogge, and Hiroshi Ishii. inform: dynamic physical affordances and constraints through shape and object ac- tuation. In UIST, volume 13, pages 417–426, 2013.
[3] John Hardy, Christian Weichel, Faisal Taher, John Vidler, and Jason Alexander. Shapeclip: Towards rapid prototyping with shape-changing displays for designers. In Proceedings of the 33rd Annual ACM Conference on Human Factors in Comput- ing Systems, pages 19–28. ACM, 2015.
[4] Ken Nakagaki, Sean Follmer, and Hiroshi Ishii. Lineform: Actuated curve interfaces for display, interaction, and constraint. In Proceedings of the 28th Annual ACM Symposium on User Interface Software & Technology, pages 333–339. ACM, 2015.
[5] Piyum Fernando, Roshan Lalintha Peiris, and Suranga Nanayakkara. I-draw: to- wards a freehand drawing assistant. In Proceedings of the 26th Australian Computer- Human Interaction Conference on Designing Futures: the Future of Design, pages 208–211. ACM, 2014.
[6] Ken Nakagaki and Yasuaki Kakehi. Comp* pass: A compass-based drawing inter- face. In CHI’14 Extended Abstracts on Human Factors in Computing Systems, pages 447–450. ACM, 2014.
[7] Gian Pangaro, Dan Maynes-Aminzade, and Hiroshi Ishii. The actuated workbench: computer-controlled actuation in tabletop tangible interfaces. In Proceedings of the 15th annual ACM symposium on User interface software and technology, pages 181– 190. ACM, 2002.
[8] James Patten and Hiroshi Ishii. Mechanical constraints as computational constraints in tabletop tangible interfaces. In Proceedings of the SIGCHI conference on Human factors in computing systems, pages 809–818. ACM, 2007.
[9] Malte Weiss, Florian Schwarz, Simon Jakubowski, and Jan Borchers. Madgets: ac- tuating widgets on interactive tabletops. In Proceedings of the 23nd annual ACM symposium on User interface software and technology, pages 293–302. ACM, 2010.
[10] JinhaLee,RehmiPost,andHiroshiIshii.Zeron:mid-airtangibleinteractionenabled by computer controlled magnetic levitation. In Proceedings of the 24th annual ACM symposium on User interface software and technology, pages 327–336. ACM, 2011.
[11] Scott Brave, Hiroshi Ishii, and Andrew Dahley. Tangible interfaces for remote col- laboration and communication. In Proceedings of the 1998 ACM conference on Computer supported cooperative work, pages 169–178. ACM, 1998.
[12] Masa Ogata and Masaaki Fukumoto. Fluxpaper: reinventing paper with dynamic actuation powered by magnetic flux. In Proceedings of the 33rd Annual ACM Con- ference on Human Factors in Computing Systems, pages 29–38. ACM, 2015.
[13] Junichi Yamaoka and Yasuaki Kakehi. depend: augmented handwriting system us- ing ferromagnetism of a ballpoint pen. In Proceedings of the 26th annual ACM symposium on User interface software and technology, pages 203–210. ACM, 2013.
[14] AnneRoudaut,AndreasRau,ChristophSterz,MaxPlauth,PedroLopes,andPatrick Baudisch. Gesture output: eyes-free output using a force feedback touch surface. In Proceedings of the SIGCHI Conference on Human Factors in Computing Systems, pages 2547–2556. ACM, 2013.

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