Jammology Physics of self-driven particles Toward solution of all jams

1. JammologyPhysics of self-driven particlesToward solution of all jams Katsuhiro Nishinari Faculty of Engineering, University of Tokyo

2. Outline • Introduction of “Jammology” Self-driven particles, methodology • Simple traffic model for ants and molecular motors • Conclusions

3. Jams Everywhere

4. School, Herd, Flock, etc.

5. What are self-driven particles (SDP)? • Vehicles, ants, pedestrians, molecular motors… • Non-Newtonian particles, which do not satisfy three laws of motion. ex. 1) Action Reaction, “force” is psychological 2) Sudden change of motion D. Helbing, Rev. Mod. Phys. vol.73 (2001) p.1067. D. Chowdhury, L. Santen and A. Schadschneider,Phys. Rep. vol.329 (2000) p.199.

6. Jammology=Collective dynamics of SDP Text book of “Jammology” • Conventional mechanics, or statistical physics cannot be directly applicable. • Rule-based approach (e.g., CA model) Numerical computations Exactly solvable models (ASEP,ZRP)

7. Subjects of Jammology • Vehicles car, bus, bicycle, airplane,etc. • Humans • Swarm, animals, ant, bee, cockroach, fly, bird,fish,etc. • Internet packet transportation • Jams in human body Blood, Kinesin, ribosome, etc. • Infectious disease, forest fire, money, etc.

8. Conventional theory of Jam= Queuing theory Out In Service Breakdown of balance of in and out causes Jam.

9. What is NOT considered in Queuing theory Exclusion effect of finite volume of SDP ＡＳＥＰ model can deal the exclusion!

10. ASEP=A toy model for jam ＡＳＥＰ（Asymmetric Simple Exclusion Process） Rule：move forward if the front is empty This is an exactly solvable model, i.e., we can calculate density distribution, flux, etc in the stationary state.

11. Who considered ASEP? Macdonald & Gibbs, Biopolymers, vol.6 (1968) p.1. Protein composition process of Ribosomes on mRNA This research has not been recognized until recently.

12. In the stationary state of TASEP, flow - density relation is Fundamental diagram of ASEP with periodic boundary condition • Flow-density・ ・ ・ ・ ・Particle-hole symmetry • Velocity-density・ ・ ・ ・ ・monotonic decrease M.Kanai, K.Nishinari and T.Tokihiro,J. Phys. A: Math. Gen., vol.39 (2006) pp.9071-9079..

13. Ultradiscrete method reveals the relation between different traffic models! J.Phys.A, vol.31 (1998) p.5439 Ultradiscrete method ASEP(Rule 184) Burgers equation CA model Macroscopic model Euler-Lagrange transformation Phys.Rev.Lett., vol.90 (2003) p.088701 OV model Car-followingmodel

14. Toward solution of all kind of jams! • Vehicular traffic cars, bus, trains,… • Pedestrians • Jams in our body

15. Traffic in ant-trail Ants drop a chemical (generically called pheromone) as they crawl forward. Other sniffing ants pick up the smell of the pheromone and follow the trail. with periodic boundary conditions

16. Ant trail traffic models and experiments • Experiments and theory • Differential equations 1) M. Burd, D. Archer, N. Aranwela and D.J. Stradling, American Natur. (2002) 2) I.D.Couzin and N.R.Franks, Proc.R.Soc.Lond.B (2002) 3) A. Dussutour, V. Fourcassie, D.Helbing and J.L. Deneubourg, Nature (2004) E.M.Rauch, M.M.Millonas and D.R.Chialvo, Phys.Lett.A (1995) Ant Langevin type equation pheromonal field : evaporation rate : ant density at x

17. qqQ Ant trail CA model One lane, uni-directional flow Dynamics: • Ants movement • Update Pheromone(creation & diffusion) f f f Parameters: q < Q, f D. Chowdhury, V. Guttal, K. Nishinari and A. Schadschneider,J.Phys.A:Math.Gen., Vol. 35 (2002) pp.L573-L577.

18. QQq Bus Route Model • Bus operation system＝In fact the ant CA！ The dynamics is the same as the ant model Loose cluster formation = buses bunching up together ｆ　　　　ｆ　　　f f

19. Modeling of pedestrians • Basic features of collective behaviours of pedestrians 1) Arch formation at exit 2) Oscillation of flow at bottleneck 3) Lane formation of counterflow at corridor • Models for evacuation Social force model (Continuous model) D.Helbing, I.Farkas and T.Vicsek, Nature (2000). Floor field model (CA model) C.Burstedde, K.Klauck, A.Schadschneider,J.Zittartz, Physica A (2001)

20. Floor field CA Model C.Burstedde, K.Klauck, A.Schadschneider,J.Zittartz, Physica A, vol.295 (2001) p.507. Pedestrians in evacuation = herding behavior = long range interaction For computational efficiency, can we describe the behavior of pedestrians by using local interactions only? Idea： Footprints = Feromone Long range interaction is imitated by local interaction through „memory on a floor“.

21. Details of FF model • Floor is devided into cells (a cell=40*40 cm2) • Exclusion principle in each cell • Parallel update • A person moves to one of nearest cells with the probability defined by „floor field(FF)“. • Two kinds of FF is introduced in each cell: 1) Dynamic FF・・・footprints of persons 2) Static FF・・・Distance to an exit

22. 4 1 2 1 Dymanic FF (DFF) Number of footprints on each cell • Leave a footprint at each cell whenever a person leave the cell • Dynamics of DFF dissipation＋diffusion dissipation・・・ diffusion・・・ • Herding behaviour = choose the cell that has more footprints • Store global information to local cells

23. Static FF (SFF) = Dijkstra metric • Distance to the destination is recorded at each cell One exit with a obstacle Two exits with four obstacles This is done by Visibility Graph and Dijkstra method. K. Nishinari, A. Kirchner, A. Namazi and A. Schadschneider, IEICE Trans. Inf. Syst., Vol.E87-D (2004) p.726.

24. Problem of “Zone partition” Application of SFF By using SFF Which door is the nearest? The ratio of an area to the total area determines the number of people who use the door in escaping from this room.

25. Probability of movement Distance between the cell (i,j) and a door. Number of footprints at the cell (i,j). Set I=1 if (i,j) is the previous direction of motion.

26. Update procedure Initial: Calculate SFF • Update DFF (dissipation & diffusion) • Calculate and determine the target cell • Resolution of conflict • Movement • Add DFF +1 Resolution of conflict Parameter All of them cannot move. One of them can move.

27. Meanings of parameters in the model kS kD • kS large: Normal (kS small: Random walk) • kD large: Panic kD /kS ・・・Panic degree (panic parameter) • large: competition small: coorporation

28. Simulations using inertia effect • There is a minimum in the evacuation time when the effect of inertia is introduced. SFF is strongly disturbed. People become less flexible to form arches. (Do not care others!) People become flexible to avoid congestion.

29. Simulation Example: Evacuation at Osaka-Sankei Hall Jams near exits.

30. Hamburg airport in Germany

31. Influence of Obstacle Placed an obstacle near exit. 2offset None Center 1offset Intensive competition. If an obstacle is placed asymmetrically, total evacuation time is reduced！ D.Helbing, I.Farkas and T.Vicsek, Nature, vol.407 (2000) p.487. A.Kirchner, K.Nishinari, and A.Schadschneider,Phys. Rev. E, vol.67 (2003) p.056122.

32. Conclusions • Traffic Jams everywhere = Jammology is interdisciplinary research among Math. , Physics and Engineering! Examples • Ant trail CA model is proposed by extending ASEP. The model is well analyzed by ZRP. • Non-monotonic variation of the average speed of the ants is confirmed by robots experiment. • Traffic jam in our body is related to diseases. • Modelling molecular motors • Jammology = Math. , Physics and Engineering

33. Conclusions • Ant trail CA model is proposed by extending ASEP. The model is well analyzed by ZRP. • Non-monotonic variation of the average speed of the ants is confirmed by robots experiment. • FF model is a local CA model with memory, which can emulating grobal behavior. • FF model is quite efficient tool for simulating pedestrian behavior. • Jammology = Math. , Physics and Engineering