Analyses of human sensitivity to redirected walking

Redirected walking allows users to walk through large-scale immersive virtual environments (IVEs) while physically remaining in a reasonably small workspace by intentionally injecting scene motion into the IVE. In a constant stimuli experiment with a two-alternative-forced-choice task we have quantified how much humans can unknowingly be redirected on virtual paths which are different from the paths they actually walk. 18 subjects have been tested in four different experiments: (E1a) discrimination between virtual and physical rotation, (E1b) discrimination between two successive rotations, (E2) discrimination between virtual and physical translation, and discrimination of walking direction (E3a) without and (E3b) with start-up. In experiment E1a subjects performed rotations to which different gains have been applied, and then had to choose whether or not the visually perceived rotation was greater than the physical rotation. In experiment E1b subjects discriminated between two successive rotations where different gains have been applied to the physical rotation. In experiment E2 subjects chose if they thought that the physical walk was longer than the visually perceived scaled travel distance. In experiment E3a subjects walked a straight path in the IVE which was physically bent to the left or to the right, and they estimate the direction of the curvature. In experiment E3a the gain was applied immediately, whereas the gain was applied after a start-up of two meters in experiment E3b. Our results show that users can be turned physically about 68% more or 10% less than the perceived virtual rotation, distances can be up- or down-scaled by 22%, and users can be redirected on an circular arc with a radius greater than 24 meters while they believe they are walking straight.

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

[2]  Jack M. Loomis,et al.  Visual perception of egocentric distance in real and virtual environments. , 2003 .

[3]  Marina Kolesnik,et al.  Estimation of travel distance from visual motion in virtual environments , 2007, TAP.

[4]  Hiroo Iwata,et al.  Powered shoes , 2006, SIGGRAPH '06.

[5]  Sharif Razzaque,et al.  Redirected Walking , 2001, Eurographics.

[6]  Bruce Bridgeman,et al.  A theory of visual stability across saccadic eye movements , 1994, Behavioral and Brain Sciences.

[7]  Mary C. Whitton,et al.  Evaluation of Reorientation Techniques for Walking in Large Virtual Environments , 2008, 2008 IEEE Virtual Reality Conference.

[8]  Victoria Interrante,et al.  Elucidating Factors that can Facilitate Veridical Spatial Perception in Immersive Virtual Environments , 2007, VR.

[9]  Bernhard E. Riecke,et al.  Can People Not Tell Left from Right in VR? Point-to-origin Studies Revealed Qualitative Errors in Visual Path Integration , 2007, 2007 IEEE Virtual Reality Conference.

[10]  Sharif Razzaque,et al.  The hand is slower than the eye: a quantitative exploration of visual dominance over proprioception , 2005, IEEE Proceedings. VR 2005. Virtual Reality, 2005..

[11]  Makoto Sato,et al.  A new step-in-place locomotion interface for virtual environment with large display system , 2002, SIGGRAPH '02.

[12]  H. Wallach Perceiving a stable environment when one moves. , 1987, Annual review of psychology.

[13]  Uwe D. Hanebeck,et al.  Motion Compression for Telepresent Walking in Large Target Environments , 2004, Presence: Teleoperators & Virtual Environments.

[14]  James Park,et al.  The Brain's Sense of Movement , 2003, The Yale Journal of Biology and Medicine.

[15]  Mary C. Whitton,et al.  Sensitivity to scene motion for phases of head yaws , 2008, APGV '08.

[16]  Uwe D. Hanebeck,et al.  Telepresence Techniques for Controlling Avatar Motion in First Person Games , 2005, INTETAIN.

[17]  Klaus H. Hinrichs,et al.  Taxonomy and Implementation of Redirection Techniques for Ubiquitous Passive Haptic Feedback , 2008, 2008 International Conference on Cyberworlds.

[18]  Jianbo Su,et al.  Motion Compression for Telepresence Locomotion , 2007, PRESENCE: Teleoperators and Virtual Environments.

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

[20]  Victoria Interrante,et al.  Distance Perception in Immersive Virtual Environments, Revisited , 2006, IEEE Virtual Reality Conference (VR 2006).

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

[22]  J. Dichgans,et al.  Visual-Vestibular Interaction: Effects on Self-Motion Perception and Postural Control , 1978 .

[23]  Sharif Razzaque,et al.  Comparing VE locomotion interfaces , 2005, IEEE Proceedings. VR 2005. Virtual Reality, 2005..

[24]  Victoria Interrante,et al.  Seven League Boots: A New Metaphor for Augmented Locomotion through Moderately Large Scale Immersive Virtual Environments , 2007, 2007 IEEE Symposium on 3D User Interfaces.

[25]  Thomas Banton,et al.  The Perception of Walking Speed in a Virtual Environment , 2005, Presence: Teleoperators & Virtual Environments.

[26]  I. Israël,et al.  Perception of two-dimensional, simulated ego-motion trajectories from optic flow , 2000, Vision Research.

[27]  Makoto Sato,et al.  Virtual locomotion system for large-scale virtual environment , 2002, Proceedings IEEE Virtual Reality 2002.

[28]  Eric Burns,et al.  Combining passive haptics with redirected walking , 2005, ICAT '05.

[29]  Timothy P. McNamara,et al.  Updating orientation in large virtual environments using scaled translational gain , 2006, APGV '06.

[30]  M. Sanders Handbook of Sensory Physiology , 1975 .

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

[32]  Hiroo Iwata,et al.  CirculaFloor , 2005, IEEE Computer Graphics and Applications.

[33]  Alexander H. Wertheim,et al.  The Direct versus Inferential controversy revisited , 2000 .

[34]  Heinz Ulbrich,et al.  Cyberwalk: Implementation of a Ball Bearing Platform for Humans , 2007, HCI.

[35]  Timo Ropinski,et al.  Moving Towards Generally Applicable Redirected Walking , 2008 .