The Impact of Encumbrance on Mobile Interactions

This paper investigates the effects of encumbrance (holding different types of objects while using mobile devices) to understand the interaction difficulties that it causes. An experiment was conducted where participants performed a target acquisition task on a touchscreen mobile phone while carrying different types of bags and boxes. Mobility was also evaluated since people carry items from one place to another. Motion capture hardware was used to track hand and arm postures to examine how holding the different types of objects caused excessive movement and instability therefore resulting in performance to decline. The results showed encumbrance and mobility caused target accuracy to decrease although input while holding the box under the non-dominant arm was more accurate and exerted quicker targeting times than holding no objects. Encumbrance affected the dominant hand more than the non-dominant hand as targeting error significantly increased and caused greater hand instability. The issues caused by encumbrance suggest the topic requires more attention from researchers and users would benefit greatly if better interaction techniques and applications are developed to counteract the problems.

[1]  G. L. Pellecchia,et al.  Postural sway increases with attentional demands of concurrent cognitive task. , 2003, Gait & posture.

[2]  Mark H. Chignell,et al.  Mobile text entry: relationship between walking speed and text input task difficulty , 2005, Mobile HCI.

[3]  Jacob O. Wobbrock,et al.  Getting off the treadmill: evaluating walking user interfaces for mobile devices in public spaces , 2008, Mobile HCI.

[4]  Antti Oulasvirta,et al.  Understanding Mobile Contexts , 2003, Mobile HCI.

[5]  Jacob O. Wobbrock,et al.  WalkType: using accelerometer data to accomodate situational impairments in mobile touch screen text entry , 2012, CHI.

[6]  Martin T. Pietrucha,et al.  FIELD STUDIES OF PEDESTRIAN WALKING SPEED AND START-UP TIME , 1996 .

[7]  Andrew Sears,et al.  How do people tap when walking? An empirical investigation of nomadic data entry , 2007, Int. J. Hum. Comput. Stud..

[8]  Stephen A. Brewster,et al.  Overcoming the Lack of Screen Space on Mobile Computers , 2002, Personal and Ubiquitous Computing.

[9]  Stephen Brewster,et al.  The Effects of Encumbrance on Mobile Gesture Interactions , 2011 .

[10]  C. Bard,et al.  Attentional demands for static and dynamic equilibrium , 2004, Experimental Brain Research.

[11]  Stephen A. Brewster,et al.  The effects of walking speed on target acquisition on a touchscreen interface , 2011, Mobile HCI.

[12]  Joaquim A. Jorge,et al.  Touch typing using thumbs: understanding the effect of mobility and hand posture , 2012, CHI.

[13]  Katrin Wolf Microinteractions beside ongoing manual tasks , 2011, Tangible and Embedded Interaction.

[14]  Jun Rekimoto,et al.  UbiComp 2005: Ubiquitous Computing, 7th International Conference, UbiComp 2005, Tokyo, Japan, September 11-14, 2005, Proceedings , 2005, UbiComp.

[15]  Scott D. Mainwaring,et al.  Living for the Global City: Mobile Kits, Urban Interfaces, and Ubicomp , 2005, UbiComp.

[16]  Virpi Roto,et al.  Interaction in 4-second bursts: the fragmented nature of attentional resources in mobile HCI , 2005, CHI.

[17]  Joanna Bergstrom-Lehtovirta,et al.  Ease of juggling: studying the effects of manual multitasking , 2011, CHI.

[18]  Enrico Rukzio,et al.  Investigating selection and reading performance on a mobile phone while walking , 2010, Mobile HCI.