Error Correction in Redirection: Rotational Manipulation for Natural Walking and Control of Walking Paths

This study proposes a novel rotational manipulation method for redirection when users attempt to turn around a corner within a virtual environment. The basic manipulation of conventional redirection can be classified into translational, rotational, and curvature manipulations. In conventional rotational manipulation, users must stop and rotate. However, this behavior is not natural in everyday walking. In addition, because the manipulated rotation varies depending on the amount of the user’s rotation, this manipulated rotation could differ from the assumed rotation if the user does not rotate by the assumed angle during this manipulation. Correspondingly, the actual walking path may deviate from the planned path. Misalignment of the walking path may cause a deviation in the interaction with an object in real space, thus resulting in collision with real-space objects and other users. We devised a basic manipulation of redirection and formulated a novel method for manipulating the amount of rotation when users rotate while moving. Using this method, we changed the axis of rotational manipulation for preventing mismatches between real and virtual environments, and set an area to correct the error in rotational manipulation. The results of our experiments demonstrated that it is possible to control the walking paths and manipulate the amount of rotation during movement without changing the amount of rotation perceived by users, and without increasing discomfort. The results demonstrated that our method is useful for manipulating the viewpoint when a user walks naturally. CCS Concepts • Human-centered computing → Virtual reality;

[1]  Robert S. Kennedy,et al.  Simulator Sickness Questionnaire: An enhanced method for quantifying simulator sickness. , 1993 .

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

[3]  Takuji Narumi,et al.  Curvature manipulation techniques in redirection using haptic cues , 2016, 2016 IEEE Symposium on 3D User Interfaces (3DUI).

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

[5]  Mary C. Whitton,et al.  Passive haptics significantly enhances virtual environments , 2001 .

[6]  Eyal Ofek,et al.  Haptic Retargeting: Dynamic Repurposing of Passive Haptics for Enhanced Virtual Reality Experiences , 2016, CHI.

[7]  Andreas M. Kunz,et al.  Planning redirection techniques for optimal free walking experience using model predictive control , 2014, 2014 IEEE Symposium on 3D User Interfaces (3DUI).

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

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

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

[11]  Mark T. Bolas,et al.  Revisiting detection thresholds for redirected walking: combining translation and curvature gains , 2016, SAP.

[12]  Takuji Narumi,et al.  Modifying an identified curved surface shape using pseudo-haptic effect , 2012, 2012 IEEE Haptics Symposium (HAPTICS).

[13]  Timothy P. McNamara,et al.  Exploring large virtual environments with an HMD when physical space is limited , 2007, APGV.

[14]  Takuji Narumi,et al.  Unlimited corridor: redirected walking techniques using visuo haptic interaction , 2016, SIGGRAPH Emerging Technologies.

[15]  Evan Suma Rosenberg,et al.  An evaluation of strategies for two-user redirected walking in shared physical spaces , 2017, 2017 IEEE Virtual Reality (VR).

[16]  E. Hodgson,et al.  Optimizing Constrained-Environment Redirected Walking Instructions Using Search Techniques , 2013, IEEE Transactions on Visualization and Computer Graphics.

[17]  Takuji Narumi,et al.  Magic table: deformable props using visuo haptic redirection , 2017, SIGGRAPH ASIA Emerging Technologies.

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

[19]  Mary C. Whitton,et al.  15 Years of Research on Redirected Walking in Immersive Virtual Environments , 2018, IEEE Computer Graphics and Applications.

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

[21]  Mary C. Whitton,et al.  Evaluation of Reorientation Techniques and Distractors for Walking in Large Virtual Environments , 2009, IEEE Transactions on Visualization and Computer Graphics.

[22]  Hannes Kaufmann,et al.  Mutual Proximity Awareness in Immersive Multi-User Virtual Environments with Real Walking , 2015, ICAT-EGVE.

[23]  Evan Suma Rosenberg,et al.  Redirected Walking Strategies in Irregularly Shaped and Dynamic Physical Environments , 2018 .