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Moving Avatars and Agents in Social Extended Reality Environments (2306.14484v1)

Published 26 Jun 2023 in cs.HC and cs.AI

Abstract: Natural interaction between multiple users within a shared virtual environment (VE) relies on each other's awareness of the current position of the interaction partners. This, however, cannot be warranted when users employ noncontinuous locomotion techniques, such as teleportation, which may cause confusion among bystanders. In this paper, we pursue two approaches to create a pleasant experience for both the moving user and the bystanders observing that movement. First, we will introduce a Smart Avatar system that delivers continuous full-body human representations for noncontinuous locomotion in shared virtual reality (VR) spaces. Smart Avatars imitate their assigned user's real-world movements when close-by and autonomously navigate to their user when the distance between them exceeds a certain threshold, i.e., after the user teleports. As part of the Smart Avatar system, we implemented four avatar transition techniques and compared them to conventional avatar locomotion in a user study, revealing significant positive effects on the observer's spatial awareness, as well as pragmatic and hedonic quality scores. Second, we introduce the concept of Stuttered Locomotion, which can be applied to any continuous locomotion method. By converting a continuous movement into short-interval teleport steps, we provide the merits of non-continuous locomotion for the moving user while observers can easily keep track of their path. Thus, while the experience for observers is similarly positive as with continuous motion, a user study confirmed that Stuttered Locomotion can significantly reduce the occurrence of cybersickness symptoms for the moving user, making it an attractive choice for shared VEs. We will discuss the potential of Smart Avatars and Stuttered Locomotion for shared VR experiences, both when applied individually and in combination.

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References (54)
  1. RemoteFusion: real time depth camera fusion for remote collaboration on physical tasks. In Proceedings of the 12th ACM SIGGRAPH international conference on virtual-reality continuum and its applications in industry. 235–242.
  2. Ashu Adhikari. 2021. Improving Spatial Orientation in Virtual Reality with Leaning-based Interfaces. Master’s thesis. Simon Fraser University, Surrey, BC, Canada. https://summit.sfu.ca/item/21858
  3. Integrating Continuous and Teleporting VR Locomotion into a Seamless” HyperJump” Paradigm. In 2021 IEEE Conference on Virtual Reality and 3D User Interfaces Abstracts and Workshops (VRW). IEEE, 370–372.
  4. Adobe Systems Incorporated. 2022. Mixamo. https://www.mixamo.com/
  5. The Effect of Field-of-View Restriction on Sex Bias in VR Sickness and Spatial Navigation Performance. In Proceedings of the 2019 CHI Conference on Human Factors in Computing Systems (Glasgow, Scotland Uk) (CHI ’19). ACM, New York, NY, USA, Article 354, 12 pages.
  6. Samuel Ang and John Quarles. 2020. GingerVR: An Open Source Repository of Cybersickness Reduction Techniques for Unity. In 2020 IEEE Conference on Virtual Reality and 3D User Interfaces Abstracts and Workshops (VRW). 460–463. https://doi.org/10.1109/VRW50115.2020.00097
  7. Teleportation without Spatial Disorientation using Optical Flow Cues. In Graphics Interface 2018. Toronto, Canada, 153 – 158.
  8. Costas Boletsis. 2017. The new era of virtual reality locomotion: A systematic literature review of techniques and a proposed typology. Multimodal Technologies and Interaction 1, 4 (2017), 24.
  9. Costas Boletsis and Jarl Erik Cedergren. 2019. Vr locomotion in the new era of virtual reality: An empirical comparison of prevalent techniques. Advances in Human-Computer Interaction 2019 (2019).
  10. John Brooke et al. 1996. SUS-A quick and dirty usability scale. Usability evaluation in industry 189, 194 (1996), 4–7.
  11. Fabio Buttussi and Luca Chittaro. 2019. Locomotion in Place in Virtual Reality: A Comparative Evaluation of Joystick, Teleport, and Leaning. IEEE Transactions on Visualization and Computer Graphics (2019).
  12. Jorge CS Cardoso. 2016. Comparison of gesture, gamepad, and gaze-based locomotion for VR worlds. In Proceedings of the 22nd ACM conference on virtual reality software and technology. 319–320.
  13. Juan S Casaneuva. 2001. Presence and co-presence in collaborative virtual environments. Ph. D. Dissertation. University of Cape Town.
  14. Virtual reality sickness: a review of causes and measurements. International Journal of Human–Computer Interaction 36, 17 (2020), 1658–1682.
  15. Outstanding: A multi-perspective travel approach for virtual reality games. In Proceedings of the annual symposium on computer-human interaction in play. 287–299.
  16. Yasin Farmani and Robert J. Teather. 2018. Viewpoint Snapping to Reduce Cybersickness in Virtual Reality. In Proceedings of the 44th Graphics Interface Conference (GI ’18). Canadian Human-Computer Communications Society, Toronto, Canada, 168–175. https://doi.org/10.20380/GI2018.23
  17. Yasin Farmani and Robert J Teather. 2020. Evaluating discrete viewpoint control to reduce cybersickness in virtual reality. Virtual Reality 24, 4 (2020), 645–664.
  18. Ajoy S Fernandes and Steven K. Feiner. 2016. Combating VR sickness through subtle dynamic field-of-view modification. In 2016 IEEE Symposium on 3D User Interfaces (3DUI). 201–210. https://doi.org/10.1109/3DUI.2016.7460053
  19. Locomotion by natural gestures for immersive virtual environments. In Proceedings of the 1st international workshop on multimedia alternate realities. 21–24.
  20. Teleportation in Virtual Reality; A Mini-Review. Frontiers in Virtual Reality (2021), 138.
  21. Walking by Cycling: A Novel In-Place Locomotion User Interface for Seated Virtual Reality Experiences. In Proceedings of the 2020 CHI Conference on Human Factors in Computing Systems. 1–12.
  22. Effects of Avatar Appearance and Locomotion on Co-Presence in Virtual Reality Collaborations. In Mensch Und Computer 2021 (Ingolstadt, Germany) (MuC ’21). Association for Computing Machinery, New York, NY, USA, 393–401. https://doi.org/10.1145/3473856.3473870
  23. Barrie Frost. 1978. The optokinetic basis of head-bobbing in the pigeon. Journal of Experimental Biology 74, 1 (1978), 187–195.
  24. GitHub. 2022. Smart Avatars GitHub Repository. https://github.com/uhhhci/TheNonContinuousToolkit
  25. Mar Gonzalez-Franco and Tabitha C Peck. 2018. Avatar embodiment. towards a standardized questionnaire. Frontiers in Robotics and AI 5 (2018), 74.
  26. Nathan Navarro Griffin and Eelke Folmer. 2019. Out-of-body locomotion: Vectionless navigation with a continuous avatar representation. In 25th ACM Symposium on Virtual Reality Software and Technology. 1–8.
  27. Style-based inverse kinematics. In ACM SIGGRAPH 2004 Papers. 522–531.
  28. Human joystick: Wii-leaning to translate in large virtual environments. In Proceedings of the 13th ACM SIGGRAPH International Conference on Virtual-Reality Continuum and its Applications in Industry. 231–234.
  29. AttrakDiff: Ein Fragebogen zur Messung wahrgenommener hedonischer und pragmatischer Qualität [AttrakDiff: A questionnaire to measure perceived hedonic and pragmatic quality]. In Mensch & Computer 2003. Springer, 187–196.
  30. Simulator sickness questionnaire: An enhanced method for quantifying simulator sickness. The international journal of aviation psychology 3, 3 (1993), 203–220.
  31. Joseph J LaViola Jr. 2000. A discussion of cybersickness in virtual environments. ACM Sigchi Bulletin 32, 1 (2000), 47–56.
  32. Myo arm: swinging to explore a VE. In Proceedings of the ACM SIGGRAPH Symposium on Applied Perception. 107–113.
  33. The Effect of Viewing a Self-Avatar on Distance Judgments in an HMD-Based Virtual Environment. Presence: Teleoperators and Virtual Environments 19, 3 (2010), 230–242.
  34. Geoff Norman. 2010. Likert scales, levels of measurement and the “laws” of statistics. Advances in health sciences education 15, 5 (2010), 625–632.
  35. Holoportation: Virtual 3d teleportation in real-time. In Proceedings of the 29th annual symposium on user interface software and technology. 741–754.
  36. Ye Pan and Anthony Steed. 2017. The impact of self-avatars on trust and collaboration in shared virtual environments. PloS one 12, 12 (2017), e0189078.
  37. Ye Pan and Anthony Steed. 2019. How foot tracking matters: The impact of an animated self-avatar on interaction, embodiment and presence in shared virtual environments. Frontiers in Robotics and AI 6 (2019), 104.
  38. Is my hand connected to my body? The impact of body continuity and arm alignment on the virtual hand illusion. Cognitive neurodynamics 6, 4 (2012), 295–305.
  39. Mini-Me: An Adaptive Avatar for Mixed Reality Remote Collaboration. Association for Computing Machinery, New York, NY, USA, 1–13. https://doi.org/10.1145/3173574.3173620
  40. HyperJumping in Virtual Vancouver: Combating Motion Sickness by Merging Teleporting and Continuous VR Locomotion in an Embodied Hands-Free VR Flying Paradigm. In Siggraph ’22 Immersive Pavilion. ACM, Vancouver, BC, Canada, 1–2. https://doi.org/10.1145/3532834.3536211
  41. Sigtrap Ltd. 2022. VR Tunneling Pro. http://www.sigtrapgames.com/VrTunnellingPro/html
  42. Depth of presence in virtual environments. Presence: Teleoperators & Virtual Environments 3, 2 (1994), 130–144.
  43. Misha Sra and Chris Schmandt. 2015. Metaspace: Full-body tracking for immersive multiperson virtual reality. In Adjunct Proceedings of the 28th Annual ACM Symposium on User Interface Software & Technology. 47–48.
  44. An ‘in the wild’experiment on presence and embodiment using consumer virtual reality equipment. IEEE transactions on visualization and computer graphics 22, 4 (2016), 1406–1414.
  45. Estimation of detection thresholds for redirected walking techniques. IEEE transactions on visualization and computer graphics 16, 1 (2009), 17–27.
  46. Mixed reality remote collaboration combining 360 video and 3d reconstruction. In Proceedings of the 2019 CHI conference on human factors in computing systems. 1–14.
  47. Sam Tregillus and Eelke Folmer. 2016. Vr-step: Walking-in-place using inertial sensing for hands free navigation in mobile vr environments. In Proceedings of the 2016 CHI Conference on Human Factors in Computing Systems. 1250–1255.
  48. Unity Technologies. 2019. Unity Standard Assets: Character Package. https://github.com/Unity-Technologies/Standard-Assets-Characters
  49. User Interface Design. 2022. AttrakDiff. http://www.attrakdiff.de/index-en.html/
  50. VRChat. 2022. Avatars 3.0. https://docs.vrchat.com/docs/avatars-30
  51. VRTK. 2022. VRTK DragWorld. https://vrtoolkit.readme.io/docs/vrtk_dragworld
  52. The Impact of Avatar Personalization and Immersion on Virtual Body Ownership, Presence, and Emotional Response. IEEE Transactions on Visualization and Computer Graphics 24, 4 (apr 2018), 1643–1652. https://doi.org/10.1109/TVCG.2018.2794629
  53. VR locomotion: walking¿ walking in place¿ arm swinging. In Proceedings of the 15th ACM SIGGRAPH Conference on Virtual-Reality Continuum and Its Applications in Industry-Volume 1. 243–249.
  54. Object location memory error in virtual and real environments. In 2017 IEEE Virtual Reality (VR). IEEE, 315–316.
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