Abstract
Navigation is the most common interactive task performed in three-dimensional virtual environments (VEs), but it is also a task that users often find difficult. We investigated how body-based information about the translational and rotational components of movement helped participants to perform a navigational search task (finding targets hidden inside boxes in a room-sized space). When participants physically walked around the VE while viewing it on a head-mounted display (HMD), they then performed 90% of trials perfectly, comparable to participants who had performed an equivalent task in the real world during a previous study. By contrast, participants performed less than 50% of trials perfectly if they used a tethered HMD (move by physically turning but pressing a button to translate) or a desktop display (no body-based information). This is the most complex navigational task in which a real-world level of performance has been achieved in a VE. Behavioral data indicates that both translational and rotational body-based information are required to accurately update one's position during navigation, and participants who walked tended to avoid obstacles, even though collision detection was not implemented and feedback not provided. A walking interface would bring immediate benefits to a number of VE applications.
- Alfano, P. L. and Michel, G. F. 1990. Restricting the field of view: Perceptual and performance effects. Perceptual Motor Skills 70, 35--45.Google ScholarCross Ref
- Bakker, N. H., Werkhoven, P. J., and Passenier, P. O. 1999. The effects of proprioceptive and visual feedback on geographical orientation in virtual environments. Presence: Teleoperat. Virt. Environ. 8, 36--53. Google ScholarDigital Library
- Bowman, D. A., Kruijff, E., Laviola, J. J., and Poupyrev, I. 2004. 3D User Interfaces: Theory and Practice. Addison-Wesley, Reading, MA. Google ScholarDigital Library
- Brooks, F. P., Airey, J., Alspaugh, J., Bell, A., Brown, R., Hill, C., Nimscheck, U., Rheingans, P., Rohlf, J., Smith, D., Turner, D., Varshney, A., Wang, Y., Weber, H., and Yuan, X. 1992. Six generations of building walkthrough: Final technical report to the National Science Foundation. Tech. rep.TR92-026, Department of Computer Science, University of North Carolina, Chapel Hill. Google ScholarDigital Library
- Brotons-Mas, J. R., O'mara, S., and Sanchez-Vives, M. V. 2006. Neural processing of spatial information: What we know about place cells and what they can tell us about presence. Presence: Teleoperat. Virt. Environ. 15, 485--499. Google ScholarDigital Library
- Chance, S. S., Gaunet, F., Beall, A. C., and Loomis, J. M. 1998. Locomotion mode affects the updating of objects encountered during travel: The contribution of vestibular and proprioceptive inputs to path integration. Presence: Teleoperat. Virt. Environ. 7, 168--178. Google ScholarDigital Library
- Cobb, S. V. G., Nichols, S., Ramsey, A., and Wilson, J. R. 1999. Virtual reality-induced symptoms and effects (VRISE). Presence: Teleoperat. Virt. Environ. 8, 169--186. Google ScholarDigital Library
- Czerwinski, M., Tan, D. S., and Robertson, G. G. 2002. Women take a wider view. In Proceedings of the SIGCHI Conference on Human Factors in Computing Systems. ACM, New York, 195--202. Google ScholarDigital Library
- Darken, R. P., Cockayne, W. R., and Carmein, D. 1997. The omni-directional treadmill: A locomotion device for virtual worlds. In Proceedings of the 10th Annual ACM Symposium on User interface Software and Technology. ACM, New York, 213--221. Google ScholarDigital Library
- De Luca, A., Mattone, R., and Robuffo Giordano, P. 2007. Acceleration-level control of the CyberCarpet. In Proceedings of the IEEE International Conference on Robotics and Automation. IEEE Press, Los Alamitos, CA, 2330--2335.Google ScholarCross Ref
- Foo, P., Warren, W. H., Duchon, A., and Tarr, M. J. 2005. Do humans integrate routes into a cognitive map? Map versus landmark-based navigation of novel shortcuts. J. Exper. Psych. Learn. Memory Cognition 31, 195--215.Google ScholarCross Ref
- Grant, S. C. and Magee, L. E. 1998. Contributions of proprioception to navigation in virtual environments. Human Factors 40, 489--497.Google ScholarCross Ref
- Gray, W. D. and Fu, W. 2001. Ignoring perfect knowledge in-the-world for imperfect knowledge in-the-head: Implications of rational analysis for interface design. In Proceedings of the SIGCHI Conference on Human Factors in Computing Systems. ACM, New York, 112--119. Google ScholarDigital Library
- Hollerbach, J. M., Checcacci, D., Noma, H., Yanagida, Y., and Tetsutani, N. 2003. Simulating side slopes on locomotion interfaces using torso forces. In Proceedings of the 11th Symposium on Haptic Interfaces for Virtual Environments and Teleoperation. IEEE Press, 91--98. Google ScholarDigital Library
- Iwata, H., Yano, H., Fukushima, H., and Noma, H. 2005. CirculaFloor: A locomotion interface using circulation of movable tiles. In Proceedings of the IEEE Virtual Reality Conference. IEEE Press, 223--230. Google ScholarDigital Library
- Klatzky, R. L., Loomis, J. M., Beall, A. C., Chance, S. S., and Golledge, R. G. 1998. Spatial updating of self-position and orientation during real, imagined, and virtual locomotion. Psych. Science 9, 293--298.Google ScholarCross Ref
- Lathrop, W. B. and Kaiser, M. K. 2002. Perceived orientation in physical and virtual enfunction of idiothetic information available. Presence: Teleoperat. Virt. Environ. 11, 19--32. Google ScholarDigital Library
- Lessels, S. and Ruddle, R. A. 2005. Movement around real and virtual cluttered environments. Presence: Teleoperat. Virt. Environ. 14, 580--596. Google ScholarDigital Library
- Lessels, S. and Ruddle, R. A. 2004. Changes in navigational behaviour produced by a wide field of view and a high fidelity visual scene. In Proceedings of the Workshop on Virtual Environments. S. Coquillart et al. Eds., Eurographics Association, 71--78. Google ScholarDigital Library
- Levenshtein, V. I. 1966. Binary codes capable of correcting deletions, insertions and reversal. Soviet Physics Doklady 10, 707--710.Google Scholar
- Loomis, J. M., Klatzky, R. L., Golledge, R. G., and Philbeck, J. W. 1999. Human navigation by path integration. In Wayfinding: Cognitive Mapping and Other Spatial Processes, R. G. Golledge Ed., John Hopkins Press, Baltimore, MD, 125--151.Google Scholar
- Pausch, R., Proffitt, D., and Williams, G. 1997. Quantifying immersion in virtual reality. In Proceedings of the 24th Annual Conference on Computer Graphics and Interactive Techniques, ACM, New York, 13--18. Google ScholarDigital Library
- Pelah, A. and Koenderink, J. J. 2007. Editorial: Walking in real and virtual environments. ACM Trans. Appl. Percep. 4, 1--4. Google ScholarDigital Library
- Péruch, P., Borel, L., Magnan, J., and Lacour, M. 2005. Direction and distance deficits in path integration after unilateral vestibular loss depend on task complexity. Cognitive Brain Research 25, 862--872.Google ScholarCross Ref
- Presson, C. C. and Montello, D. R. 1994. Updating after rotational and translational body movements: Coordinate structure of perspective space. Perception 23, 1447--1455.Google ScholarCross Ref
- Razzaque, S., Swapp, D., Slater, M., Whitton, M. C., and Steed, A. 2002. Redirected walking in place. In Proceedings of the Workshop on Virtual Environments. W. Stürzlinger and S. Müller Eds., Eurographics Association, 123--130. Google ScholarDigital Library
- Riecke, B. E. and Bülthoff, H. H. 2004. Spatial updating in real and virtual environments: Contribution and interaction of visual and vestibular cues. In Proceedings of the 1st Symposium on Applied Perception in Graphics and Visualization. ACM, New York, 9--17. Google ScholarDigital Library
- Ruddle, R. A. and Péruch, P. 2004. Effects of proprioceptive feedback and environmental characteristics on spatial learning in virtual environments. Int. J. Hum. Comput. Stud. 60, 299--326. Google ScholarDigital Library
- Riecke, B. E., Van Veen, H. A. H. C., and Bülthoff, H. H. 2002. Visual homing is possible without landmarks: A path integration study in virtual reality. Presence: Teleoperat. Virt. Environ. 11, 443--473. Google ScholarDigital Library
- Rieser, J. J. 1989. Access to knowledge of spatial structure at novel points of observation. J. Exper. Psych. Learn. Memory Cognition 15, 1157--1165.Google ScholarCross Ref
- Ruddle, R. A. and Lessels, S. 2006. For efficient navigational search humans require full physical movement but not a rich visual scene. Psych. Science 17, 460--465.Google ScholarCross Ref
- Ruddle, R. A. 2005. The effect of trails on first-time and subsequent navigation in a virtual environment. In Proceedings of the IEEE Virtual Reality Conference. IEEE Press, 115--122. Google ScholarDigital Library
- Ruddle, R. A. and Jones, D. M. 2001. Movement in cluttered virtual environments. Presence: Teleoperat. Virt. Environ. 10, 511--524. Google ScholarDigital Library
- Ruddle, R. A. 2001. Navigation: Am I really lost or virtually there? In Engineering Psychology and Cognitive Ergonomics vol. 6, D. Harris Ed., Ashgate, Burlington, VT, 135--142.Google Scholar
- Ruddle, R. A., Payne, S. J., and Jones, D. M. 1999. Navigating large-scale virtual environments: What differences occur between helmet-mounted and desk-top displays? Presence: Teleoperat. Virt. Environ. 8, 157--168. Google ScholarDigital Library
- Ruddle, R. A., Payne, S. J., and Jones, D. M. 1997. Navigating buildings in “desk-top” virtual environments: Experimental investigations using extended navigational experience. J. Exper. Psycho. Appl. 3, 143--159.Google ScholarCross Ref
- Slater, M., Usoh, M., and Steed, A. 1995. Taking steps: The influence of a walking technique on presence in virtual reality. ACM Trans. Comput. Hum. Interact. 2, 201--219. Google ScholarDigital Library
- Steck, S. D. and Mallot, H. A. 2000. The role of global and local landmarks in virtual environment navigation. Presence: Teleoperat. Virt. Environ. 9, 69--83. Google ScholarDigital Library
- Templeman, J. N., Denbrook, P. S., and Sibert, L. E. 1999. Virtual locomotion: Walking in place through virtual environments. Presence: Teleoperat. Virt. Environ. 8, 598--617. Google ScholarDigital Library
- Usoh, M., Arthur, K., Whitton, M. C., Bastos, R., Steed, A., Slater, M., And Brooks, F. P. 1999. Walking -> walking-in-place -> flying, in virtual environments. In Proceedings of the 26th Annual Conference on Computer Graphics and interactive Techniques. ACM, New York, 359--364. Google ScholarDigital Library
- Vijayakar, A. and Hollerbach, J. 2002. Effect of turning strategy on maneuvering ability using the Treadport locomotion interface. Presence: Teleoperat. Virt. Environ. 11, 247--258. Google ScholarDigital Library
- Waller, D. 2000. Individual differences in spatial learning from computer-simulated environments. J. Exper. Psych. Appl. 6, 307--321.Google ScholarCross Ref
- Waller, D, Hunt, E., and Knapp, D. 1998. The transfer of spatial knowledge in virtual environment training. Presence: Teleoperat. Virt. Environ., 7, 129--143. Google ScholarDigital Library
- Waller, D., Loomis, J. M., and Haun, D. B. M. 2004. Body-based senses enhance knowledge of directions in large-scale environments. Psychonomic Bull. Rev. 11, 157--163.Google ScholarCross Ref
- Whitton, M. C., Cohn, J. V., Feasel, J., Zimmons, P., Razzaque, S., Poulton, S. J., Mcleod, B., and Brooks, F. P. 2005. Comparing VE locomotion interfaces. In Proceedings of the IEEE Virtual Reality Conference. IEEE Press, 123--130. Google ScholarDigital Library
- Winter, D. A. 1990. Biomechanics and Motor Control of Human Movement 2nd Ed. Wiley-Interscience, New York.Google Scholar
- Witmer, B. G., Bailey, J. H., Knerr, B. W., and Parsons, K. C. 1996. Virtual spaces and real-world places: Transfer of route knowledge. Int. J. Hum. Comput. Stud. 45, 413--428. Google ScholarDigital Library
- Witmer, B. G. and Kline, P. B. 1998. Judging perceived and traversed distance in virtual environments. Presence: Teleoperat. Virt. Environ. 7, 144--167. Google ScholarDigital Library
- Witmer, B. G., Sadowski, W. J., and Finkelstein, N. M. 2002. VE-based training strategies for acquiring survey knowledge. Presence: Teleoperat. Virt. Environ. 11, 1--18. Google ScholarDigital Library
- Zanbaka, C. A., Lok, B. C., Babu, S. V., Ulinski, A. C., and Hodges, L. F. 2005. Comparison of path visualizations and cognitive measures relative to travel techniques in a virtual environment. IEEE Trans. Visual. Comput. Graph. 11, 694--705. Google ScholarDigital Library
Index Terms
- The benefits of using a walking interface to navigate virtual environments
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