Stop-and-go waves are commonly observed in traffic and pedestrian flows. In traffic theory they are described by phase transitions of metastable models. The self-organization phenomenon occurs due to inertia mechanisms but requires fine tuning of the parameters. Here, a novel explanation for stop-and-go waves based on stochastic effects is presented for pedestrian dynamics. We show that the introduction of specific coloured noises in a stable microscopic model allows to describe realistic pedestrian stop-and-go behaviour without requirement of metastability and phase transition. We compare simulation results of the stochastic model to real pedestrian trajectories and discuss plausible values for the model’s parameters
International audienceSelf-driven particle systems can describe many self-organized phenomena. Promi...
Stop-and-go waves, also called phantom jams, are often observed in real traffic flows but can be pro...
The increasing importance and magnitude of large-scale events in our society calls for continuous re...
A class of microscopic stochastic models is proposed to describe 1D pedestrian trajectories obtained...
Stop-and-go waves in single-file movement are a phenomenon that is ob- served empirically in pedestr...
Force-based models describe pedestrian dynamics in analogy to classical mechanics by a system of sec...
AbstractBased on the typical phenomena of pedestrian movement, an extended optimal velocity model is...
We propose a microscopic stochastic model to describe 1D pedestrian trajectories obtained in laborat...
Hyperbolic PDE can be used to describe the macroscopic dynamics of traffic flow. Models of traffic ...
International audienceWe analyze numerically some macroscopic models of pedestrian motion to compare...
AbstractWe analyze numerically some macroscopic models of pedestrian motion to compare their capabil...
AbstractPhase separation into a jammed phase and a free-flow phase is a well understood feature obse...
The `tipping point' phenomenon is discussed as a mathematical object, and related to the behaviour o...
Self-driven particle systems can describe many self-organized phenomena. Prominentexamples are oscil...
Certain aspects of traffic flow measurements imply the existence of a phase transition. Models known...
International audienceSelf-driven particle systems can describe many self-organized phenomena. Promi...
Stop-and-go waves, also called phantom jams, are often observed in real traffic flows but can be pro...
The increasing importance and magnitude of large-scale events in our society calls for continuous re...
A class of microscopic stochastic models is proposed to describe 1D pedestrian trajectories obtained...
Stop-and-go waves in single-file movement are a phenomenon that is ob- served empirically in pedestr...
Force-based models describe pedestrian dynamics in analogy to classical mechanics by a system of sec...
AbstractBased on the typical phenomena of pedestrian movement, an extended optimal velocity model is...
We propose a microscopic stochastic model to describe 1D pedestrian trajectories obtained in laborat...
Hyperbolic PDE can be used to describe the macroscopic dynamics of traffic flow. Models of traffic ...
International audienceWe analyze numerically some macroscopic models of pedestrian motion to compare...
AbstractWe analyze numerically some macroscopic models of pedestrian motion to compare their capabil...
AbstractPhase separation into a jammed phase and a free-flow phase is a well understood feature obse...
The `tipping point' phenomenon is discussed as a mathematical object, and related to the behaviour o...
Self-driven particle systems can describe many self-organized phenomena. Prominentexamples are oscil...
Certain aspects of traffic flow measurements imply the existence of a phase transition. Models known...
International audienceSelf-driven particle systems can describe many self-organized phenomena. Promi...
Stop-and-go waves, also called phantom jams, are often observed in real traffic flows but can be pro...
The increasing importance and magnitude of large-scale events in our society calls for continuous re...