Abstract
Understanding human decision making is a key requirement to improve crowd simulation models so that they can better mimic real human behavior. It is often difficult to study human decision making during dangerous situations because of the complexity of the scenarios and situations to be simulated. Immersive virtual reality offers the possibility to carry out such experiments without exposing participants to real danger. In the real world, it has often been observed that people tend to follow others in certain situations (e.g., unfamiliar environments or stressful situations). In this paper, we study human following behavior when it comes to exit choice during an evacuation of a train station. We have carried out immersive VR experiments under different levels of stress (alarm only or alarm plus fire), and we have observed how humans consistently tend to follow the crowd regardless of the levels of stress. Our results show that decision making is strongly influenced by the behavior of the virtual crowd: the more virtual people running, the more likely are participants to simply follow others. The results of this work could improve behavior simulation models during crowd evacuation, and thus build more plausible scenarios for training firefighters.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Ahn J, Wang N, Thalmann D, Boulic R (2012) Within-crowd immersive evaluation of collision avoidance behaviors. In: Proceedings of the 11th ACM SIGGRAPH international conference on virtual-reality continuum and its applications in industry, pp 231–238. ACM
Argelaguet F, Olivier A-H, Bruder G, Pettré J, Lécuyer (2015) A Virtual proxemics: locomotion in the presence of obstacles in large immersive projection environments. In VR
Bruneau J, Olivier A-H, Pettre J (2015) Going through, going around: a study on individual avoidance of groups. IEEE Trans Vis Comput Gr 21(4):520–528
Cassol VJ, Testa ES, Jung CR, Usman M, Faloutsos P, Berseth G, Kapadia M, Badler NI, Musse SR (2017) Evaluating and optimizing evacuation plans for crowd egress. IEEE Comput Gr Appl 37(4):60–71
Cialdini RB (1993) Influence: the psychology of persuasion (Rev. ed.). Morrow, New York
Coultas J C (2004) When in Rome... an evolutionary perspective on conformity. Gr Process Intergr Relat 7(4):317–331
Ennis C, Peters C, O’Sullivan C (2008) Perceptual evaluation of position and orientation context rules for pedestrian formations. In: Proceedings of the 5th symposium on Applied perception in graphics and visualization, pp 75–82. ACM
Ennis C, Peters C, O’Sullivan C (2011) Perceptual effects of scene context and viewpoint for virtual pedestrian crowds. ACM Trans Appl Percept (TAP) 8(2):10:1–10:22
Gonzalez-Franco M, Lanier J (2017) Model of illusions and virtual reality. Front Psychol 8:1125
Gonzalez-Franco M, Slater M, Birney ME, Swapp D, Haslam SA, Reicher SD (2018) Participant concerns for the learner in a virtual reality replication of the milgram obedience study. PloS One 13(12):e0209704
Gupta N, Singh A, Butail S (2017) The effect of instructional priming on postural responses to virtual crowds. In: Virtual humans and crowds for immersive environments (VHCIE), IEEE, 1–8
Guy S J, Chhugani J, Curtis S, Dubey P, Lin M, Manocha D (2010) Pledestrians: a least-effort approach to crowd simulation. In: Proceedings of the 2010 ACM SIGGRAPH/Eurographics symposium on computer animation, Eurographics Association, 119–128
Guy S J, Kim S, Lin M C, Manocha D (2010) Simulating heterogeneous crowd behaviors using personality trait theory. In: Proceedings of the 2011 ACM SIGGRAPH/Eurographics symposium on computer animation, pp 43–52. ACM
Guy SJ, Van Den Berg J, Liu W, Lau R, Lin MC, Manocha D (2012) A statistical similarity measure for aggregate crowd dynamics. ACM Trans Graph (TOG) 31(6):190
Haworth B, Usman M, Berseth G, Kapadia M, Faloutsos P (2015) Evaluating and optimizing level of service for crowd evacuations. In: Proceedings of the 8th ACM SIGGRAPH conference on motion in games, MIG ’15, pp 91–96, New York, NY, USA, ACM
Kazdin AE, Kazdin AE (2000) Encyclopedia of psychology, vol 2. American Psychological Association, Washington
Knob P, Balotin M, Musse SR (2018) Simulating crowds with ocean personality traits. In: Proceedings of the 18th international conference on intelligent virtual agents, pp 233–238. ACM
Kyriakou M, Chrysanthou Y (2018) How responsiveness, group membership and gender affect the feeling of presence in immersive virtual environments populated with virtual crowds. In: Proceedings of the 11th annual international conference on motion, interaction, and games, p 12. ACM
Lerner A, Chrysanthou Y, Shamir A, Cohen-Or D (2010) Context-dependent crowd evaluation. Comput Graph. Forum 29(7):2197–2206
Llobera J, Spanlang B, Ruffini G, Slater M (2010) Proxemics with multiple dynamic characters in an immersive virtual environment. ACM Trans Appl Percept (TAP) 8(1):3
Maples-Keller JL, Yasinski CW, Manjin N, Rothbaum BO (2017) Virtual reality-enhanced extinction of phobias and post-traumatic stress. Neurotherapeutics 14:554–563
Moussaïd M, Kapadia M, Thrash T, Sumner RW, Gross M, Helbing D, Hölscher C (2016) Crowd behaviour during high-stress evacuations in an immersive virtual environment. J R Soc Interface 13(122):20160414
Narang, S, Best A, Randhavane T, Shapiro A, Manocha D (2016) Pedvr: simulating gaze-based interactions between a real user and virtual crowds. In: Proceedings of the 22nd ACM conference on virtual reality software and technology, pp 91–100. ACM, 2016
Olivier A-H, Bruneau J, Cirio G, Pettré J (2014) A virtual reality platform to study crowd behaviors. Transp Res Procedia 2:114–122
Olivier A-H, Marin A, Crétual A, Berthoz A, Pettré J (2013) Collision avoidance between two walkers: role-dependent strategies. Gait Posture 38(4):751–756
Ondřej J, Pettré J, Olivier A-H, Donikian S (2010) A synthetic-vision based steering approach for crowd simulation. ACM Trans Gr (TOG) 29(4):123
Pelechano N, Allbecky JM (2016) Feeling crowded yet?: crowd simulations for VR. In: Virtual humans and crowds for immersive environments (VHCIE), pp 17–21. IEEE
Pelechano N, Badler NI (2006) Modeling crowd and trained leader behavior during building evacuation. IEEE Comput Gr Appl 26(6):80–86
Pelechano N, Stocker C, Allbeck J, Badler N (2008) Being a part of the crowd: towards validating vr crowds using presence. In: Proceedings of the 7th international joint conference on autonomous agents and multiagent systems, vol 1, p 136–142
Pelechano Gómez N, Stocker C, Allbeck J, Badler N (2007) Feeling crowded? exploring presence in virtual crowds. In: Proceedings of PRESENCE 2007, pp 373–376
Ríos A, Palomar M, Pelechano N (2018) Users’ locomotor behavior in collaborative virtual reality. In: Proceedings of the 11th annual international conference on motion, interaction, and games, pp 15. ACM
Rojas FA, Yang HS (2013) Immersive human-in-the-loop hmd evaluation of dynamic group behavior in a pedestrian crowd simulation that uses group agent-based steering. In: Proceedings of the 12th ACM SIGGRAPH international conference on virtual-reality continuum and its applications in industry, VRCAI ’13, pp 31–40, New York, NY, USA, ACM
Ríos A, Pelechano N (2018) Follower behavior in a virtual environment. In: Virtual humans and crowds in immersive environments (VHCIE), March
Sohre N, Mackin C, Interrante V, Guy SJ (2017) Evaluating collision avoidance effects on discomfort in virtual environments. In: Virtual humans and crowds for immersive environments (VHCIE), pp 1–5. IEEE
Steed A, Pan Y, Watson Z, Slater M (2018) “We wait”—the impact of character responsiveness and self embodiment on presence and interest in an immersive news experience. Front Robot AI 5:112
Turner A, Penn A (2002) Encoding natural movement as an agent-based system: an investigation into human pedestrian behaviour in the built environment. Environ Plan B Plan Des 29(4):473–490
Turner A, Penn A (2007) Evolving direct perception models of human behavior in building systems. In: Pedestrian and Evacuation Dynamics 2005. Springer, Berlin, Heidelberg, pp 411–422
Van Toll WG, Cook AF, Geraerts R (2012) Real-time density-based crowd simulation. Comput Anim Virtual Worlds 23(1):59–69
Wolinski D, Guy SJ, Olivier A-H, Lin M, Manocha D, Pettré J (2014) Parameter estimation and comparative evaluation of crowd simulations. Comput Graph Forum 33(2):303–312
Acknowledgements
This work was partly funded by the Spanish Ministry of Economy, Industry and Competitiveness under Grant No. TIN2017-88515-C2-1-R.
Author information
Authors and Affiliations
Corresponding author
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Ríos, A., Pelechano, N. Follower behavior under stress in immersive VR. Virtual Reality 24, 683–694 (2020). https://doi.org/10.1007/s10055-020-00428-8
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10055-020-00428-8