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1. Visual model of locomotion reproduces lanes and stripes in crossing human crowds

   https://doi.org/10.1167/jov.25.9.2681  

   Veprek, Kyra; Feldmann, Sina; Warren, William (July 2025, Journal of Vision)

   The visual control of locomotion has been modeled for individual pedestrian behavior; however, this approach has not been applied to collective human behavior, where spontaneous pattern formation is often observed. We hypothesize that an empirical visual model of human locomotion will reproduce the emergent pattern of lanes and stripes observed in crossing flows, when two groups of pedestrians walk through each other at crosswalks or intersections. Mullick, et al. (2022) manipulated the crossing angle between two groups and found an invariant property: stripe orientation is perpendicular to the mean walking direction (i.e. 90˚ to the bisectrix of the crossing angle). Here we determine the combination of model components required to simulate human-like stripes: (i) steering to a goal (Fajen & Warren, 2003), (ii) collision avoidance with opponents (Bai, 2022; Veprek & Warren, VSS 2023), and (iii) alignment with neighbors (Dachner, et al., 2022), together called the SCruM (Self-organized Collective Motion) model. We performed multi-agent simulations of the data from Mullick et al. (2022), using fixed parameters and initial conditions from the dataset. There were two sets of participants (N=36, 38) with 18 or 19 per group. Crossing angle varied from 60˚ to 180˚ (30˚ intervals), with ~17 trials per condition. The minimal model necessary to reproduce stripe formation consists of the goal and collision avoidance components. Mean stripe orientation did not differ from 90˚ to the bisectrix (BF10 < 0.01, decisive). However, the SD of heading during crossing was significantly larger than the human data (p<0.001), whereas the SD of speed was significantly smaller (p<0.001). Thus, the ratio of heading/speed adjustments is lower than previously found, implying the need to reparameterize model components for walking in groups. In sum, steering to a goal and collision avoidance are sufficient to explain stripe formation in crossing flows, while alignment is unnecessary. 

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2. Formation of lanes and stripes in crossing pedestrian flows using an empirical human model

   https://doi.org/10.1051/epjconf/202533404011  

   Feldmann, Sina; Veprek, Kyra; Warren, William H (January 2025, EPJ Web of Conferences: Traffic and Granular Flow 2024)

   Nicolas, A; Bain, N; Douin, A; Ramos, O; Furno, A (Ed.)

   Crossing flows of pedestrians result in collective motions containing self-organized lanes or stripes. Over a wide range of crossing angles, stripe orientation is observed to be perpendicular to the mean walking direction. Here, we test the behavioral components needed to reproduce the lanes and stripes in human data using an empirical, vision-based pedestrian model (Visual SCruM). We examine combinations of (i) steering toward a goal, (ii) collision avoidance, and (iii) alignment (both with and without visual occlusion). The minimal model sufficient to reproduce perpendicular stripes was the combination of a common goal and collision avoidance, although the addition of alignment with occlusion better approximated human heading adjustments. However, the model overestimated the variation in heading and underestimated the variation in speed, suggesting that recalibration of the collision avoidance component is needed. 

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3. Behavioral dynamics of pedestrians and crowds. International handbook of ecological psychology.

   Warren, WH (December 2025, Routledge)

   Romero, V; Segundo-Ortin, M; Wagman, J; Nonaka, T (Ed.)

   Where does the organization in behavior come from? Ecological psychology seeks to explain adaptive behavior as self-organized, emerging from the dynamics of agent-environment interactions, without assuming such organization a priori. This chapter offers an accessible introduction to the behavioral dynamics approach to modeling perception and action, applied to the case of human locomotion and crowd behavior. Most models of such behavior are ‘omniscient’, presuming accurate knowledge of the environmental state, but we find that information-based ‘visual’ models more closely capture human data. At the individual level, a locomotor trajectory emerges from an agent’s interactions with goals and obstacles, as attractors and repellers appear, shift, and bifurcate. At the dyad level, pedestrian interactions governed by visual control laws yield coordinated movements such as interception, collision avoidance, and following. At the collective level, these local interactions generate human ‘flocking’, crowd bifurcations, and patterns of lanes and stripes in crossing flows of pedestrians. By adopting an empirical, bottom-up, information-based approach, behavioral dynamics helps explain individual and collective behavior as resulting from a process of self-organized pattern formation, without appealing to internal plans or external commands. 

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4. Transverse modulational dynamics of quenched patterns

   https://doi.org/10.1063/5.0170039  

   Dunn, Sierra; Goh, Ryan; Krewson, Benjamin (June 2024, Chaos: An Interdisciplinary Journal of Nonlinear Science)

   We study the modulational dynamics of striped patterns formed in the wake of a planar directional quench. Such quenches, which move across a medium and nucleate pattern-forming instabilities in their wake, have been shown in numerous applications to control and select the wavenumber and orientation of striped phases. In the context of the prototypical complex Ginzburg–Landau and Swift–Hohenberg equations, we use a multiple-scale analysis to derive a one-dimensional viscous Burgers’ equation, which describes the long-wavelength modulational and defect dynamics in the direction transverse to the quenching motion, that is, along the quenching line. We show that the wavenumber selecting properties of the quench determine the nonlinear flux parameter in the Burgers’ modulation equation, while the viscosity parameter of the Burgers’ equation is naturally determined by the transverse diffusivity of the pure stripe state. We use this approximation to accurately characterize the transverse dynamics of several types of defects formed in the wake, including grain boundaries and phase-slips. 

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5. ADOPT: A system for Alerting Drivers to Occluded Pedestrian Traffic

   https://doi.org/10.1016/j.vehcom.2023.100601  

   Alali, Abrar; Olariu, Stephan; Jain, Shubham (June 2023, Vehicular Communications)

   Recent statistics reveal an alarming increase in accidents involving pedestrians (especially children) crossing the street. A common philosophy of existing pedestrian detection approaches is that this task should be undertaken by the moving cars themselves. In sharp departure from this philosophy, we propose to enlist the help of cars parked along the sidewalk to detect and protect crossing pedestrians. In support of this goal, we propose ADOPT: a system for Alerting Drivers to Occluded Pedestrian Traffic. ADOPT lays the theoretical foundations of a system that uses parked cars to: (1) detect the presence of a group of crossing pedestrians – a crossing cohort; (2) predict the time the last member of the cohort takes to clear the street; (3) send alert messages to those approaching cars that may reach the crossing area while pedestrians are still in the street; and, (4) show how approaching cars can adjust their speed, given several simultaneous crossing locations. Importantly, in ADOPT all communications occur over very short distances and at very low power. Our extensive simulations using SUMO-generated pedestrian and car traffic have shown the effectiveness of ADOPT in detecting and protecting crossing pedestrians. 

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