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abstract

Designing Exocentric Pedestrian Navigation for AR Head Mounted Displays

Published: 25 April 2020 Publication History

Abstract

Augmented reality (AR) is gradually becoming used for navigation in urban environments, allowing users to see instructions in their physical environment. However, viewing this information through a smartphone's screen is not ideal, as it can cause users to become inattentive to their surroundings. AR head-mounted displays (HMD) have the potential to overcome this issue by integrating navigational information into the user's field of view (FOV). While work has explored the design of turn-by-turn egocentric AR navigation interfaces, little work has explored the design of exocentric interfaces, which provide the user with an overview of their desired route. In response to this, we examined the impact of three different exocentric AR map displays on pedestrian navigation performance and user experience. Our work highlights pedestrian safety concerns and provides design implications for future AR HMD pedestrian navigation interfaces.

References

[1]
2013. Directions - Google Glass. (2013). https: //support.google.com/glass/answer/3086042?hl=en
[2]
2018. 1Texture City. (2018). https://assetstore.unity.com/packages/3d/environments/urban/1texture-city-112740
[3]
2019. Use Live View on Google Maps. (2019). https://support.google.com/maps/answer/9332056? co=GENIE.Platform
[4]
Eswar Anandapadmanaban, Jesslyn Tannady, Johannes Norheim, Dava Newman, and Jeff Hoffman. 2018. Holo-SEXTANT: An augmented reality planetary EVA navigation interface. 48th International Conference on Environmental Systems.
[5]
Ronald T. Azuma. 2019. The road to ubiquitous consumer augmented reality systems. Human Behavior and Emerging Technologies 1, 1 (jan 2019), 26--32.
[6]
Gaurav Bhorkar. 2017. A survey of augmented reality navigation. arXiv preprint arXiv:1708.05006 (2017).
[7]
Mark Billinghurst, Huidong Bai, Gun Lee, and Robert Lindeman. 2014. Developing handheld augmented reality interfaces. In The Oxford Handbook of Virtuality.
[8]
Mark Billinghurst, Adrian Clark, Gun Lee, and others. 2015. A survey of augmented reality. Foundations and Trends® in Human--Computer Interaction 8, 2--3 (2015), 73--272.
[9]
John Brooke. 1996. SUS - A quick and dirty usability scale. Usability evaluation in industry 189, 194 (1996), 4--7.
[10]
Jaewoo Chung, Francesco Pagnini, and Ellen Langer. 2016. Mindful navigation for pedestrians: Improving engagement with augmented reality. Technology in Society 45 (may 2016), 29--33.
[11]
Brian F. Goldiez, Ali M. Ahmad, and Peter A. Hancock. 2007. Effects of augmented reality display settings on human way?nding performance. IEEE Transactions on Systems, Man and Cybernetics Part C: Applications and Reviews 37, 5 (sep 2007), 839--845.
[12]
Google. 2019. Developing the First AR Experience for Google Maps (Google I/O'19) . (2019). https://www.youtube.com/watch?v=14wedZy90Tw
[13]
Sandra G. Hart and Lowell E. Staveland. 1988. Development of NASA-TLX (Task Load Index): Results of Empirical and Theoretical Research. Advances in Psychology 52, C (jan 1988), 139--183.
[14]
PA Howarth and M Finch. 1999. The nauseogenicity of two methods of navigating within a virtual environment. Applied Ergonomics 30, 1 (1999), 39--45.
[15]
Ira E. Hyman, S. Matthew Boss, Breanne M. Wise, Kira E. McKenzie, and Jenna M. Caggiano. 2010. Did you see the unicycling clown? Inattentional blindness while walking and talking on a cell phone. Applied Cognitive Psychology 24, 5 (jul 2010), 597--607.
[16]
Richie Jose, Gun A Lee, and Mark Billinghurst. 2016. A comparative study of simulated augmented reality displays for vehicle navigation. In Proceedings of the 28th Australian conference on computer-human interaction. ACM, 40--48.
[17]
Zach Kinstner. 2015. Hovercast VR Menu: Power at your Fingertips. (2015). http://blog.leapmotion.com/hovercast-vr-menu-power-fingertips/
[18]
Kiyoshi Kiyokawa. 2015. Head-mounted display technologies for augmented reality. Fundamentals of Wearable Computing and Augmented Reality (2015), 59--84.
[19]
Pascal Knierim, Steffen Maurer, Katrin Wolf, and Markus Funk. 2018. Quadcopter-projected in-situ navigation cues for improved location awareness. In Conference on Human Factors in Computing Systems - Proceedings, Vol. 2018-April. Association for Computing Machinery.
[20]
Eun Jin Lee and Susan K Frazier. 2011. The ef?cacy of acupressure for symptom management: A systematic review. Journal of pain and symptom management 42, 4 (2011), 589--603.
[21]
J. Lehikoinen and R. Suomela. 2002. WalkMap: Developing an augmented reality map application for wearable computers. Virtual Reality 6, 1 (2002), 33--44.
[22]
Marvin Levine. 1982. You-are-here maps: Psychological considerations. Environment and behavior 14, 2 (1982), 221--237.
[23]
Yuji Makimura, Aya Shiraiwa, Masashi Nishiyama, and Yoshio Iwai. 2019. Visual effects of turning point and travel direction for outdoor navigation using head-mounted display. In International Conference on Human-Computer Interaction. Springer, 235--246.
[24]
Pete Pachal. 2013. 2D Navigation. (2013). https://mashable.com/2013/05/08/google-glass-pov/
[25]
Tumasch Reichenbacher. 2004. Mobile Cartography. Ph.D. Dissertation. Technische Universität München.
[26]
Tilman Reinhardt. 2019. Google AI Blog: Using global localization to improve navigation. (2019). https://ai.googleblog.com/2019/02/using-global-localization-to-improve.html
[27]
R. ShaynaVE Rosenbaum, Hugo Spiers, and Véronique Bohbot. 2018. Behavioral studies of human spatial navigation. In Human Spatial Navigation. Princeton University Press, 23--44.
[28]
Sonja Schneider and Klaus Bengler. 2019. Virtually the same? Analysing pedestrian behaviour by means of virtual reality. Transportation Research Part F: Traffic Psychology and Behaviour (2019).
[29]
Jan Stryjak and Mayuran Sivakumaran. 2019. GSMA Intelligence - The Mobile Economy 2019. (2019). https://www.gsmaintelligence.com/research/2019/02/the-mobile-economy-2019/731/
[30]
Christopher D Wickens, Justin G Hollands, Simon Banbury, and Raja Parasuraman. 2015. Engineering psychology and human performance. Psychology Press.

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  • (2024)Assessing the Value of Information in an Augmented Reality City ExperienceFuture Internet10.3390/fi1612044816:12(448)Online publication date: 2-Dec-2024
  • (2024)Augmented Reality on the Move: A Systematic Literature Review for Vulnerable Road UsersProceedings of the ACM on Human-Computer Interaction10.1145/36764908:MHCI(1-30)Online publication date: 24-Sep-2024
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  1. Designing Exocentric Pedestrian Navigation for AR Head Mounted Displays

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    cover image ACM Conferences
    CHI EA '20: Extended Abstracts of the 2020 CHI Conference on Human Factors in Computing Systems
    April 2020
    4474 pages
    ISBN:9781450368193
    DOI:10.1145/3334480
    Permission to make digital or hard copies of part or all of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for third-party components of this work must be honored. For all other uses, contact the Owner/Author.

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    Published: 25 April 2020

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    Author Tags

    1. augmented reality
    2. exocentric navigation
    3. head mounted display
    4. maps
    5. pedestrian navigation
    6. virtual reality
    7. wayfinding

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    Cited By

    View all
    • (2024)Assessing the Value of Information in an Augmented Reality City ExperienceFuture Internet10.3390/fi1612044816:12(448)Online publication date: 2-Dec-2024
    • (2024)Augmented Reality on the Move: A Systematic Literature Review for Vulnerable Road UsersProceedings of the ACM on Human-Computer Interaction10.1145/36764908:MHCI(1-30)Online publication date: 24-Sep-2024
    • (2024)Meaningful Interaction with Digital Data in MotionAdjunct Proceedings of the 26th International Conference on Mobile Human-Computer Interaction10.1145/3640471.3686643(1-3)Online publication date: 21-Sep-2024
    • (2024)Augmented Reality Navigation: A SurveyInternational Journal of Human–Computer Interaction10.1080/10447318.2024.2431757(1-17)Online publication date: 28-Nov-2024
    • (2023)Simulating Wearable Urban Augmented Reality Experiences in VR: Lessons Learnt from Designing Two Future Urban InterfacesMultimodal Technologies and Interaction10.3390/mti70200217:2(21)Online publication date: 16-Feb-2023
    • (2023)Combined Framework of Multicriteria Methods to Identify Quality Attributes in Augmented Reality ApplicationsMathematics10.3390/math1113283411:13(2834)Online publication date: 24-Jun-2023
    • (2023)UbiPose: Towards Ubiquitous Outdoor AR Pose Tracking using Aerial MeshesProceedings of the 29th Annual International Conference on Mobile Computing and Networking10.1145/3570361.3613263(1-16)Online publication date: 2-Oct-2023
    • (2023)Evaluating Augmented Reality Landmark Cues and Frame of Reference Displays with Virtual RealityIEEE Transactions on Visualization and Computer Graphics10.1109/TVCG.2023.324707829:5(2710-2720)Online publication date: May-2023
    • (2023)Reading and Walking with Smart Glasses: Effects of Display and Control Modes on SafetyInternational Journal of Human–Computer Interaction10.1080/10447318.2023.227652940:23(7875-7891)Online publication date: 7-Nov-2023
    • (2022)Exploring the Design of a Mixed-Reality 3D Minimap to Enhance Pedestrian Satisfaction in Urban Exploratory NavigationFuture Internet10.3390/fi1411032514:11(325)Online publication date: 10-Nov-2022
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