The Perceived Naturalness of Virtual Locomotion Methods Devoid of Explicit Leg Movements

Walking-In-Place (WIP) techniques have potential in terms of solving the problem arising when an immersive virtual environment offers a larger freedom of movement than the physical environment. Such techniques are particularly useful when the spatial constraints are very prominent, as they are likely to be in relation to immersive gaming systems located in the homes of consumers. However, most existing WIP techniques rely on movement of the legs which may cause users, wearing a head mounted display, to unintentionally move. This paper details a within-subjects study performed with the intention of investigating how two alternative types of gestural input relying on arm and hip movements compare to the traditional WIP gesture and keyboard input. Visual feedback was delivered through a head-mounted display and auditory feedback was provided by means of a 16-channel surround sound system. The gestures were evaluated in terms of perceived naturalness, presence and real world positional drift. The results suggest that both WIP and arm swinging are perceived as significantly more natural than hip movement and the keyboard configuration. However, arm swinging better matched real walking in terms of energy expenditure and led to significantly less positional drift.

[1]  Béat Hirsbrunner,et al.  Active Walking Interface for Human-Scale Virtual Environment , 2005 .

[2]  Gerd Bruder,et al.  A taxonomy for deploying redirection techniques in immersive virtual environments , 2012, 2012 IEEE Virtual Reality Workshops (VRW).

[3]  Mary C. Whitton,et al.  Walking > walking-in-place > flying, in virtual environments , 1999, SIGGRAPH.

[4]  Stefania Serafin,et al.  Unintended positional drift and its potential solutions , 2013, 2013 IEEE Virtual Reality (VR).

[5]  F. Lacquaniti,et al.  Motor Patterns in Walking. , 1999, News in physiological sciences : an international journal of physiology produced jointly by the International Union of Physiological Sciences and the American Physiological Society.

[6]  Sharif Razzaque,et al.  Redirected Walking in Place , 2002, EGVE.

[7]  Tae-Seong Kim,et al.  Real-Time Recognition of Daily Human Activities Using a Single Tri-Axial Accelerometer , 2010, 2010 5th International Conference on Embedded and Multimedia Computing.

[8]  Paul Skalski,et al.  Mapping the road to fun: Natural video game controllers, presence, and game enjoyment , 2011, New Media Soc..

[9]  D. Panescu,et al.  Emerging Technologies , 2008, IEEE Engineering in Medicine and Biology Magazine.

[10]  F. Bremmer,et al.  Perception of self-motion from visual flow , 1999, Trends in Cognitive Sciences.

[11]  Michèle Courant,et al.  Walking-pad: a step-in-place locomotion interface for virtual environments , 2004, ICMI '04.

[12]  Ryan P. McMahan,et al.  Shadow walking: An unencumbered locomotion technique for systems with under-floor projection , 2011, 2011 IEEE Virtual Reality Conference.

[13]  Chris Crawford,et al.  Chris Crawford on Game Design , 2003 .

[14]  Betsy Williams Sanders,et al.  Evaluation of walking in place on a Wii balance board to explore a virtual environment , 2011, TAP.

[15]  Mel Slater,et al.  Taking steps: the influence of a walking technique on presence in virtual reality , 1995, TCHI.

[16]  Stefania Serafin,et al.  Tapping-In-Place: Increasing the naturalness of immersive walking-in-place locomotion through novel gestural input , 2013, 2013 IEEE Symposium on 3D User Interfaces (3DUI).

[17]  Maud Marchal,et al.  Shake-your-head: revisiting walking-in-place for desktop virtual reality , 2010, VRST '10.

[18]  Michael J. Singer,et al.  Measuring Presence in Virtual Environments: A Presence Questionnaire , 1998, Presence.

[19]  Colin Ware,et al.  Vection with large screen 3D imagery , 1996, CHI Conference Companion.

[20]  Suzanne Weghorst,et al.  Virtusphere: Walking in a Human Size VR “Hamster Ball” , 2008 .

[21]  Behrang Keshavarz,et al.  Illusory Self-Motion in Virtual Environments , 2014, Handbook of Virtual Environments, 2nd ed..

[22]  Colin Potts,et al.  Design of Everyday Things , 1988 .

[23]  Hiroo Iwata,et al.  CirculaFloor [locomotion interface] , 2005, IEEE Computer Graphics and Applications.

[24]  Daniel Västfjäll,et al.  The Actor-Observer Effect in Virtual Reality Presentations , 2001, Cyberpsychology Behav. Soc. Netw..

[25]  Hiroo Iwata,et al.  String walker , 2007, SIGGRAPH '07.

[26]  Jonathan Freeman,et al.  A Cross-Media Presence Questionnaire: The ITC-Sense of Presence Inventory , 2001, Presence: Teleoperators & Virtual Environments.

[27]  Joaquim A. Jorge,et al.  A New Approach to Walking in Place , 2013, INTERACT.

[28]  Heinrich H. Bülthoff,et al.  Scene consistency and spatial presence increase the sensation of self-motion in virtual reality , 2005, APGV '05.

[29]  Hiroo Iwata,et al.  Path Reproduction Tests Using a Torus Treadmill , 1999, Presence.

[30]  E. Paul Zehr,et al.  Modulation of cutaneous reflexes in arm muscles during walking: further evidence of similar control mechanisms for rhythmic human arm and leg movements , 2003, Experimental Brain Research.

[31]  R Beckett,et al.  An evaluation of the kinematics of gait by minimum energy. , 1968, Journal of biomechanics.

[32]  Mary C. Whitton,et al.  GUD WIP: Gait-Understanding-Driven Walking-In-Place , 2010, 2010 IEEE Virtual Reality Conference (VR).

[33]  Rudy Darken,et al.  The omni-directional treadmill: a locomotion device for virtual worlds , 1997, UIST '97.

[34]  Mel Slater,et al.  Depth of Presence in Virtual Environments , 1994, Presence: Teleoperators & Virtual Environments.

[35]  Albert A. Rizzo,et al.  FAAST: The Flexible Action and Articulated Skeleton Toolkit , 2011, 2011 IEEE Virtual Reality Conference.

[36]  Bruce Bridgeman,et al.  Perception & control of self-motion , 1991 .

[37]  Makoto Sato,et al.  Virtual Locomotion Interface with Ground Surface Simulation , 2003, ICAT.

[38]  Gerd Bruder,et al.  Estimation of Detection Thresholds for Redirected Walking Techniques , 2010, IEEE Transactions on Visualization and Computer Graphics.

[39]  Klaus H. Hinrichs,et al.  Reorientation during Body Turns , 2009, EGVE/ICAT/EuroVR.

[40]  Jonathan Steuer,et al.  Defining virtual reality: dimensions determining telepresence , 1992 .

[41]  N Sekiya,et al.  The invariant relationship between step length and step rate during free walking , 1996 .

[42]  Julian Williams,et al.  The implementation of a novel walking interface within an immersive display , 2010, 2010 IEEE Symposium on 3D User Interfaces (3DUI).

[43]  Wiebren Zijlstra,et al.  Voluntary and involuntary adaptation of walking to temporal and spatial constraints , 1995 .

[44]  Mel Slater,et al.  How Colorful Was Your Day? Why Questionnaires Cannot Assess Presence in Virtual Environments , 2004, Presence: Teleoperators & Virtual Environments.

[45]  Mary C. Whitton,et al.  LLCM-WIP: Low-Latency, Continuous-Motion Walking-in-Place , 2008, 2008 IEEE Symposium on 3D User Interfaces.

[46]  Mel Slater,et al.  Steps and ladders in virtual reality , 1994 .

[47]  Mel Slater,et al.  The Virtual Treadmill: A Naturalistic Metaphor for Navigation in Immersive Virtual Environments , 1995, Virtual Environments.