Self-organized queuing and scale-free behavior in real escape panic

Saloma, Caesar; Perez, G. J. P.; Tapang, Giovanni; Lim, May; Palmes-Saloma, Cynthia

doi:10.1073/pnas.2031912100

Cited by 178 publications

(118 citation statements)

References 12 publications

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“…A readily accessible parameter that is related with clogging is the mean avalanche size s . In fact, the distribution of avalanche (burst) sizes has been reported to decay exponentially both in the case of the silo [22] and in mice exiting a very small room [29]. This exponential-which can be explained by random alternation between particle and gap propagations [30] and also described in terms of a probabilistic model [22]-is characterized by the mean avalanche size s .…”

Section: Resultsmentioning

confidence: 99%

Role of driving force on the clogging of inert particles in a bottleneck

et al. 2014

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We present numerical results of the effect that the driving force has on the clogging probability of inert particles passing through a bottleneck. When the driving force is increased by four orders of magnitude, the mean avalanche size remains almost unaltered (increases 1.6 times) while the flow rate and the avalanche duration display strong dependence on this magnitude. This indicates that in order to characterize the ability of a system to clog, the right variable to consider is the number of particles that pass through the outlet. The weak dependence of this magnitude on the driving force is explained in terms of the average kinetic energy of the flowing grains that has to be dissipated in order to get an arch stabilized.

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Section: Resultsmentioning

confidence: 99%

Role of driving force on the clogging of inert particles in a bottleneck

et al. 2014

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“…Herding is also observed when the orientation in an unfamiliar environment is unsatisfactory (Quarantelli 1957;Keating 1982;Johnson 1987;Elliott and Smith 1993;Helbing, Farkas, and Vicsek 2000b;Saloma et al 2003): People either follow other people who are believed to know the best way, or they use the exit they are familiar with (typically the main exit they have entered). This can cause severe congestion at a few exits, and high pressures, as all people want to leave at the same time.…”

Section: Figure 30mentioning

confidence: 99%

Self-Organized Pedestrian Crowd Dynamics: Experiments, Simulations, and Design Solutions

Helbing

Buzna

Johansson

et al. 2005

Transportation Science

1,258

773

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T o test simulation models of pedestrian flows, we have performed experiments for corridors, bottleneck areas, and intersections. Our evaluations of video recordings show that the geometric boundary conditions are not only relevant for the capacity of the elements of pedestrian facilities, they also influence the time gap distribution of pedestrians, indicating the existence of self-organization phenomena. After calibration of suitable models, these findings can be used to improve design elements of pedestrian facilities and egress routes. It turns out that "obstacles" can stabilize flow patterns and make them more fluid. Moreover, intersecting flows can be optimized, utilizing the phenomenon of "stripe formation." We also suggest increasing diameters of egress routes in stadia, theaters, and lecture halls to avoid long waiting times for people in the back, and shock waves due to impatience in cases of emergency evacuation. Moreover, zigzag-shaped geometries and columns can reduce the pressure in panicking crowds. The proposed design solutions are expected to increase the efficiency and safety of train stations, airport terminals, stadia, theaters, public buildings, and mass events in the future. As application examples we mention the evacuation of passenger ships and the simulation of pilgrim streams on the Jamarat bridge. Adaptive escape guidance systems, optimal way systems, and simulations of urban pedestrian flows are addressed as well.

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“…Examples of microscopic models are cellular automata models (e.g., [10,[25][26][27][28][29][30][31]), lattice gas models (e.g., [32]), social force models (e.g., [4,11,[33][34][35]), motion planning with velocity obstacles (e.g., [36,37]), agent-based models (e.g., [38][39][40]), game theoretic models (e.g., [41][42][43]), approaches based on experiments with animals (e.g., [44][45][46][47]), and hybrid models (e.g., [48]). Cellular automata models and lattice gas models partition the space into grids or hexagons.…”

Section: Evacuation Models and Crowd Dynamicsmentioning

confidence: 99%

“…Agent-based models describe the evacuation system by simulating each evacuee (or a household [40]) as an autonomous agent with certain behavior and situated in an environment, and studying the emergent system behavior. In contrast, approaches based on experiments with animals study escape dynamics with real biological agents such as mice [44] or ants [45][46][47]. Hybrid models combine the previously mentioned microscopic models to benefit from their advantages and to avoid their drawbacks.…”

Section: Evacuation Models and Crowd Dynamicsmentioning

confidence: 99%

Integrating Decentralized Indoor Evacuation with Information Depositories in the Field

Zhao

Winter

Tomko

2017

IJGI

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Abstract:The lonelier evacuees find themselves, the riskier become their wayfinding decisions. This research supports single evacuees in a dynamically changing environment with risk-aware guidance. It deploys the concept of decentralized evacuation, where evacuees are guided by smartphones acquiring environmental knowledge and risk information via exploration and knowledge sharing by peer-to-peer communication. Peer-to-peer communication, however, relies on the chance that people come into communication range with each other. This chance can be low. To bridge between people being not at the same time at the same places, this paper suggests information depositories at strategic locations to improve information sharing. Information depositories collect the knowledge acquired by the smartphones of evacuees passing by, maintain this information, and convey it to other passing-by evacuees. Multi-agent simulation implementing these depositories in an indoor environment shows that integrating depositories improves evacuation performance: It enhances the risk awareness and consequently increases the chance that people survive and reduces their evacuation time. For evacuating dynamic events, deploying depositories at staircases has been shown more effective than deploying them in corridors.

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Self-organized queuing and scale-free behavior in real escape panic

Cited by 178 publications

References 12 publications

Role of driving force on the clogging of inert particles in a bottleneck

Role of driving force on the clogging of inert particles in a bottleneck

Self-Organized Pedestrian Crowd Dynamics: Experiments, Simulations, and Design Solutions

Integrating Decentralized Indoor Evacuation with Information Depositories in the Field

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