Go-Through: Disabling Collision to Access Obstructed Paths and Open Occluded Views in Social VR

Social Virtual Reality (VR) offers new opportunities for designing social experiences, but at the same time, it challenges the usability of VR as other avatars can block paths and occlude one's avatar's view. In contrast to designing VR similar to the physical reality, we allow avatars to go through and to see through other avatars. In detail, we vary the property of avatars to collide with other avatars. To better understand how such properties should be implemented, we also explore multimodal feedback when avatars collide with each other. Results of a user study show that multimodal feedback on collision yields to a significantly increased sensation of presence in Social VR. Moreover, while the loss of collision (the possibility to go through other avatars) causes a significant decrease of felt co-presence, qualitative feedback showed that the ability to walk through avatars can ease to access spots of interest. Finally, we observed that the purpose of Social VR determines how useful the possibility to walk through avatars is. We conclude with design guidelines that distinguish between Social VR with a priority on social interaction, Social VR supporting education and information, and hybrid Social VR enabling education and information in a social environment.

[1]  Fabien Ferlay,et al.  Vibrotactile feedback for collision awareness , 2015, BCS HCI.

[2]  Daria Tsoupikova,et al.  Real-time diagnostic data in multi-user virtual reality post-stroke therapy , 2016, SIGGRAPH ASIA VR Showcase.

[3]  Michael Lewis,et al.  An Experimental Comparison of Three Methods for Collision Handling in Virtual Environments , 1997 .

[4]  Sergio Garrido-Jurado,et al.  Procedurally generated virtual reality from 3D reconstructed physical space , 2016, VRST.

[5]  Sabarish V. Babu,et al.  Comparison of Travel Techniques in a Complex, Multi-Level 3D Environment , 2007, 2007 IEEE Symposium on 3D User Interfaces.

[6]  Kristopher J. Blom,et al.  Floor-based Audio-Haptic Virtual Collision Responses , 2012, ICAT/EGVE/EuroVR.

[7]  Dooley J. Murphy Bodiless embodiment: A descriptive survey of avatar bodily coherence in first-wave consumer VR applications , 2017, 2017 IEEE Virtual Reality (VR).

[8]  I. Herbst,et al.  Comparing force magnitudes by means of vibro-tactile, auditory, and visual feedback , 2005, IEEE International Workshop on Haptic Audio Visual Environments and their Applications.

[9]  Rainer Stiefelhagen,et al.  Capability for Collision Avoidance of Different User Avatars in Virtual Reality , 2018, HCI.

[10]  Alejandro M. García-Alonso,et al.  Solving the collision detection problem , 1994, IEEE Computer Graphics and Applications.

[11]  Kensuke Harada,et al.  Obstacle Avoidance Method in Real Space for Virtual Reality Immersion , 2018, 2018 IEEE International Symposium on Mixed and Augmented Reality (ISMAR).

[12]  Patrick Baudisch,et al.  VirtualSpace - Overloading Physical Space with Multiple Virtual Reality Users , 2018, CHI.

[13]  Eyal Ofek,et al.  VRoamer: Generating On-The-Fly VR Experiences While Walking inside Large, Unknown Real-World Building Environments , 2019, 2019 IEEE Conference on Virtual Reality and 3D User Interfaces (VR).

[14]  Hans Stokking,et al.  Social VR Platform: Building 360-degree Shared VR Spaces , 2017, TVX.

[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]  Thomas P. Kersten,et al.  Development of a Virtual Museum Including a 4d Presentation of Building History in Virtual Reality , 2017 .

[17]  Misha Sra Asymmetric Design Approach and Collision Avoidance Techniques For Room-scale Multiplayer Virtual Reality , 2016, UIST.

[18]  Fabio Ganovelli,et al.  Collision Handling for Virtual Environments , 2001, Eurographics.

[19]  Kristopher J. Blom,et al.  Virtual travel collisions , 2013, ACM Trans. Appl. Percept..

[20]  John W. Boyse,et al.  Interference detection among solids and surfaces , 1979, CACM.

[21]  Andrea Bönsch,et al.  Collision avoidance in the presence of a virtual agent in small-scale virtual environments , 2016, 2016 IEEE Symposium on 3D User Interfaces (3DUI).

[22]  Taesung Kim,et al.  A team-based firefighter training platform using the virtual environment , 2010, VRCAI '10.

[23]  Marc Erich Latoschik,et al.  Any “Body” There? Avatar Visibility Effects in a Virtual Reality Game , 2018, 2018 IEEE Conference on Virtual Reality and 3D User Interfaces (VR).

[24]  Victoria Interrante,et al.  Evaluating collision avoidance effects on discomfort in virtual environments , 2017, 2017 IEEE Virtual Humans and Crowds for Immersive Environments (VHCIE).

[25]  Marilyn Keller,et al.  Obstacles Awareness Methods from Occupancy Map for Free Walking in VR , 2019, 2019 IEEE Conference on Virtual Reality and 3D User Interfaces (VR).

[26]  Jing Fan,et al.  Simulation and Evaluation of Three-User Redirected Walking Algorithm in Shared Physical Spaces , 2019, 2019 IEEE Conference on Virtual Reality and 3D User Interfaces (VR).

[27]  Anthony Scavarelli,et al.  VR Collide! Comparing Collision-Avoidance Methods Between Co-located Virtual Reality Users , 2017, CHI Extended Abstracts.

[28]  Steve Benford,et al.  Crowded collaborative virtual environments , 1997, CHI.

[29]  Yiorgos Chrysanthou,et al.  Interaction with virtual crowd in Immersive and semi‐Immersive Virtual Reality systems , 2017, Comput. Animat. Virtual Worlds.

[30]  Sandra Poeschl,et al.  Measuring Co-Presence and Social Presence in Virtual Environments - Psychometric Construction of a German Scale for a Fear of Public Speaking Scenario. , 2015, Studies in health technology and informatics.

[31]  Hannes Kaufmann,et al.  Mutual collision avoidance during walking in real and collaborative virtual environments , 2018, I3D.

[32]  Bum-Jae You,et al.  Be closer as you being there: HMD-based social interaction system , 2016, SIGGRAPH ASIA VR Showcase.

[33]  Elizabeth F. Churchill,et al.  Collaborative virtual environments: An introductory review of issues and systems , 1998, Virtual Reality.

[34]  Kensuke Harada,et al.  Walking Assist Method for VR Zombie , 2019, 2019 12th Asia Pacific Workshop on Mixed and Augmented Reality (APMAR).

[35]  Linda R. Elliott,et al.  Comparing the effects of visual-auditory and visual-tactile feedback on user performance: a meta-analysis , 2006, ICMI '06.

[36]  Mel Slater,et al.  An Experimental Exploration of Presence in Virtual Environments , 2013 .

[37]  Michael A. Zmuda,et al.  Collision prediction and prevention in a simultaneous two-user immersive virtual environment , 2013, 2013 IEEE Virtual Reality (VR).

[38]  Norman I. Badler,et al.  Virtual Training via Vibrotactile Arrays , 2008, PRESENCE: Teleoperators and Virtual Environments.

[39]  Norman I. Badler,et al.  Collision Awareness Using Vibrotactile Arrays , 2007, 2007 IEEE Virtual Reality Conference.

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

[41]  Michael J. Singer,et al.  The Factor Structure of the Presence Questionnaire , 2005, Presence: Teleoperators & Virtual Environments.

[42]  Frank B. ter Haar,et al.  Virtual reality conferencing: multi-user immersive VR experiences on the web , 2018, MMSys.

[43]  J. B. Brooke,et al.  SUS: A 'Quick and Dirty' Usability Scale , 1996 .

[44]  Christine Mégard,et al.  The Effect of Haptic, Visual and Auditory Feedback on an Insertion Task on a 2-Screen Workbench , 2003 .

[45]  R. Reulke,et al.  Remote Sensing and Spatial Information Sciences , 2005 .

[46]  Hojun Lee,et al.  A VR serious game for fire evacuation drill with synchronized tele-collaboration among users , 2016, VRST.