Stability of multi-population traffic flows

Amaury Hayat; Benedetto Piccoli; Shengquan Xiang; Amaury Hayat; Benedetto Piccoli; Shengquan Xiang

doi:10.3934/nhm.2023038

Networks and Heterogeneous Media

2023, Volume 18, Issue 2: 877-905. doi: 10.3934/nhm.2023038

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Stability of multi-population traffic flows

1.
CERMICS, École des Ponts ParisTech, 6–8, Avenue Blaise Pascal, Cité Descartes—Champs sur Marne, 77455 Marne la Vallée, France
2.
Department of Mathematical Sciences and Center for Computational and Integrative Biology, Rutgers University–Camden, 303 Cooper St, Camden, NJ, USA
3.
School of Mathematical Sciences, Peking University, 100871, Beijing, P. R. China

Received: 05 January 2022 Revised: 09 January 2023 Accepted: 11 January 2023 Published: 14 March 2023

Traffic waves, known also as stop-and-go waves or phantom jams, appear naturally as traffic instabilities, also in confined environments as a ring-road. A multi-population traffic is studied on a ring-road, comprised of drivers with stable and unstable behavior. There exists a critical penetration rate of stable vehicles above which the system is stable, and under which the system is unstable. In the latter case, stop-and-go waves appear, provided enough cars are on the road. The critical penetration rate is explicitly computable, and, in reasonable situations, a small minority of aggressive drivers is enough to destabilize an otherwise very stable flow. This is a source of instability that a single population model would not be able to explain. Also, the multi-population system can be stable below the critical penetration rate if the number of cars is sufficiently small. Instability emerges as the number of cars increases, even if the traffic density remains the same (i.e., number of cars and road size increase similarly). This shows that small experiments could lead to deducing imprecise stability conditions.
- traffic flow,
- multi-population,
- stability,
- stop-and-go,
- control
Citation: Amaury Hayat, Benedetto Piccoli, Shengquan Xiang. Stability of multi-population traffic flows[J]. Networks and Heterogeneous Media, 2023, 18(2): 877-905. doi: 10.3934/nhm.2023038

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Abstract

Traffic waves, known also as stop-and-go waves or phantom jams, appear naturally as traffic instabilities, also in confined environments as a ring-road. A multi-population traffic is studied on a ring-road, comprised of drivers with stable and unstable behavior. There exists a critical penetration rate of stable vehicles above which the system is stable, and under which the system is unstable. In the latter case, stop-and-go waves appear, provided enough cars are on the road. The critical penetration rate is explicitly computable, and, in reasonable situations, a small minority of aggressive drivers is enough to destabilize an otherwise very stable flow. This is a source of instability that a single population model would not be able to explain. Also, the multi-population system can be stable below the critical penetration rate if the number of cars is sufficiently small. Instability emerges as the number of cars increases, even if the traffic density remains the same (i.e., number of cars and road size increase similarly). This shows that small experiments could lead to deducing imprecise stability conditions.

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