The fat thumb: using the thumb's contact size for single-handed mobile interaction

Modern mobile devices allow a rich set of multi-finger interactions that combine modes into a single fluid act, for example, one finger for panning blending into a two-finger pinch gesture for zooming. Such gestures require the use of both hands: one holding the device while the other is interacting. While on the go, however, only one hand may be available to both hold the device and interact with it. This mostly limits interaction to a single-touch (i.e., the thumb), forcing users to switch between input modes explicitly. In this paper, we contribute the Fat Thumb interaction technique, which uses the thumb's contact size as a form of simulated pressure. This adds a degree of freedom, which can be used, for example, to integrate panning and zooming into a single interaction. Contact size determines the mode (i.e., panning with a small size, zooming with a large one), while thumb movement performs the selected mode. We discuss nuances of the Fat Thumb based on the thumb's limited operational range and motor skills when that hand holds the device. We compared Fat Thumb to three alternative techniques, where people had to precisely pan and zoom to a predefined region on a map and found that the Fat Thumb technique compared well to existing techniques.

[1]  Patrick Baudisch,et al.  Back-of-device interaction allows creating very small touch devices , 2009, CHI.

[2]  Kang Shi,et al.  PressureFish: a method to improve control of discrete pressure-based input , 2008, CHI.

[3]  Fong-Chin Su,et al.  A kinematic method to calculate the workspace of the trapeziometacarpal joint , 2004, Proceedings of the Institution of Mechanical Engineers. Part H, Journal of engineering in medicine.

[4]  John F. Hughes,et al.  Navigating documents with the virtual scroll ring , 2004, UIST '04.

[5]  Simon Rogers,et al.  AnglePose: robust, precise capacitive touch tracking via 3d orientation estimation , 2011, CHI.

[6]  Patrick Baudisch,et al.  Understanding touch , 2011, CHI.

[7]  Steven K. Feiner,et al.  Rubbing and tapping for precise and rapid selection on touch-screen displays , 2008, CHI.

[8]  Patrick Baudisch,et al.  Precise selection techniques for multi-touch screens , 2006, CHI.

[9]  Patrick Baudisch,et al.  The generalized perceived input point model and how to double touch accuracy by extracting fingerprints , 2010, CHI.

[10]  Xiang Cao,et al.  Detecting and leveraging finger orientation for interaction with direct-touch surfaces , 2009, UIST '09.

[11]  Sebastian Boring,et al.  HandSense: discriminating different ways of grasping and holding a tangible user interface , 2009, Tangible and Embedded Interaction.

[12]  Nambu Hirotaka,et al.  Reassessing current cell phone designs: using thumb input effectively , 2003, CHI Extended Abstracts.

[13]  Benjamin B. Bederson,et al.  AppLens and launchTile: two designs for one-handed thumb use on small devices , 2005, CHI.

[14]  Andreas Butz,et al.  Touch projector: mobile interaction through video , 2010, CHI.

[15]  Benjamin B. Bederson,et al.  Target size study for one-handed thumb use on small touchscreen devices , 2006, Mobile HCI.

[16]  Ravin Balakrishnan,et al.  Pressure widgets , 2004, CHI.

[17]  Jefferson Y. Han Low-cost multi-touch sensing through frustrated total internal reflection , 2005, UIST.

[18]  Jun Rekimoto,et al.  GraspZoom: zooming and scrolling control model for single-handed mobile interaction , 2009, Mobile HCI.

[19]  David R. Morse,et al.  Using while moving: HCI issues in fieldwork environments , 2000, TCHI.

[20]  Xiang Cao,et al.  ShapeTouch: Leveraging contact shape on interactive surfaces , 2008, 2008 3rd IEEE International Workshop on Horizontal Interactive Human Computer Systems.

[21]  Juan Pablo Hourcade,et al.  Evaluating one handed thumb tapping on mobile touchscreen devices , 2008, Graphics Interface.

[22]  Michael Rohs,et al.  Characteristics of pressure-based input for mobile devices , 2010, CHI.

[23]  Ken Hinckley,et al.  Sensor synaesthesia: touch in motion, and motion in touch , 2011, CHI.

[24]  Kenneth C. Smith,et al.  A multi-touch three dimensional touch-sensitive tablet , 1985, CHI '85.

[25]  Mike Wu,et al.  Multi-finger and whole hand gestural interaction techniques for multi-user tabletop displays , 2003, UIST '03.

[26]  Stéphane Huot,et al.  TapTap and MagStick: improving one-handed target acquisition on small touch-screens , 2008, AVI '08.

[27]  Eric Lecolinet,et al.  MicroRolls: expanding touch-screen input vocabulary by distinguishing rolls vs. slides of the thumb , 2009, CHI.

[28]  Chris Harrison,et al.  TapSense: enhancing finger interaction on touch surfaces , 2011, UIST.

[29]  Stephen A. Brewster,et al.  Pressure-based text entry for mobile devices , 2009, Mobile HCI.

[30]  Sriram Subramanian,et al.  PressureText: pressure input for mobile phone text entry , 2009, CHI Extended Abstracts.

[31]  William Buxton,et al.  ThinSight: versatile multi-touch sensing for thin form-factor displays , 2007, UIST.

[32]  Eric Lecolinet,et al.  Clutch-free panning and integrated pan-zoom control on touch-sensitive surfaces: the cyclostar approach , 2010, CHI.

[33]  David Kim,et al.  Creating malleable interactive surfaces using liquid displacement sensing , 2008, 2008 3rd IEEE International Workshop on Horizontal Interactive Human Computer Systems.

[34]  Gregory D. Abowd,et al.  Exploring Continuous Pressure Input for Mobile Phones , 2006 .

[35]  Jose L. Contreras-Vidal,et al.  Studies in One-Handed Mobile Design: Habit, Desire and Agility , 2006 .

[36]  Niels Henze,et al.  100,000,000 taps: analysis and improvement of touch performance in the large , 2011, Mobile HCI.

[37]  Stephen A. Brewster,et al.  Pressure-based menu selection for mobile devices , 2010, Mobile HCI.

[38]  Eric Horvitz,et al.  ZoneZoom: map navigation for smartphones with recursive view segmentation , 2004, AVI.

[39]  Benjamin B. Bederson,et al.  ThumbSpace: Generalized One-Handed Input for Touchscreen-Based Mobile Devices , 2007, INTERACT.

[40]  Clifton Forlines,et al.  Glimpse: a novel input model for multi-level devices , 2005, CHI EA '05.

[41]  Eric Horvitz,et al.  Sensing techniques for mobile interaction , 2000, UIST '00.