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851-0585-03L 3 Credits DS D-GESS

Self-Organized Traffic Flow and Human Coordination in Space and Time

Lecturers & Examiners: Prof. Dr. Dirk Helbing
VVZ CR n/a

Last Updated: 2026-02-05 15:24:19

Abstract

The lectures present mathematical models of human coordination in space and time, addressing subjects like pedestrian motion, crowd dynamics, freeway traffic and material flows in networks. Particular attention is paid to the spontaneous formation (emergent self-organization) and breakdown of cooperative spatio-temporal patterns of motion.

Objective

Students should gain an overview over the many interesting phenomena observed in traffic flows, crowds, and other multi-component systems characterized by interactive motion in space and time, such as material flows in logistics and production. Moreover, participants of the course should learn how to set up mathematical models describing such systems. Finally, one should be able to derive in mathematical terms typical spatio-temporal characteristics of the systems under consideration. It is expected that the corresponding formalisms can be well formulated and explained.

Content

The lectures present mathematical models of human coordination in space and time, addressing subjects like pedestrian motion, crowd dynamics, freeway traffic and material flows in networks. A particular focus will be on the spontaneous formation (emergent self-organization) and breakdown of cooperative spatio-temporal patterns of motion. We will answer questions such as: Why are vehicles sometimes stopped by so-called ``phantom traffic jams'', although they all like to drive fast? What are the mechanisms behind stop-and-go traffic? Why are there several different kinds of congestion, and how are they related? Why do most traffic jams occur considerably before the road capacity is reached? Can a temporary reduction of the traffic volume cause a lasting traffic jam? Under which conditions can speed limits speed up traffic? Why do pedestrians moving in opposite directions normally organize in lanes, while similar systems are ``freezing by heating''? How do pedestrians manage to cross different flow directions smoothly, often without stopping? Why do self-organizing systems tend to reach an optimal state? What is layer formation and the ``zipper effect''? Why do panicking pedestrians produce dangerous deadlocks or phenomena like ``crowd turbulence''? Can one understand business cycles through unstable material flows in networks? How can one describe the interaction of traffic flows in urban street networks? And how can those flows be optimally coordinated by a self-organized traffic light control?

Resources

Lecture Notes

The script is a copyrighted and preliminary first draft of an upcoming book on traffic dynamicsintended for publication. Feedback on this script is strongly encouraged. (Please report unclearparagraph and mistakes.)

Literature

[1] Dirk Helbing, Verkehrsdynamik (Springer, Berlin, 1997). [2] Dirk Helbing, Traffic and related self-driven many-particle systems. Reviews of Modern Physics 73(4), 1067-1141 (2001). [3] Additional references will be given in each chapter of the lecture/script.

General Information

Language
English
Levels
DS
Frequency
Yearly recurring

Examination

Type
end-of-semester examination
Depending on the number of exam candidates, a written exam (90min, if more than 5 candidates) or individual oral exams (30min each, if less than 6 candidates) will be offered (not optional). In exceptional cases, a seminar thesis (simulation study) will be considered alternatively.

Course Components

Type Title Time & Place Hours
lecture Self-Organized Traffic Flow and Human Coordination in Space and Time
  • Tue 10:15-12:00 (LFO G 25)
2 h weekly

Offered In