Rigorous Derivation of Nonlinear Scalar Conservation Laws from Follow-the-Leader Type Models via Many Particle Limit

Francesco, Marco Di; Rosini, Massimiliano D.

doi:10.1007/s00205-015-0843-4

Cited by 84 publications

(106 citation statements)

References 51 publications

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“…We consider now a space non-homogeneous scenario and we report results for the Boltzmann-type description of traffic flow coming from (10) under the binary interaction model (7) along with the quasi-invariant scaling (13). We start by giving the details of the discretisation technique.…”

Section: Boltzmann-type Model With and Without Stochasticitymentioning

confidence: 99%

“…Figure 5: Test 3. Left: density and mean speed at the computational time t = 6 obtained with the hydrodynamic model (20) and the Boltzmann-type kinetic model (10) with D = 0 in the binary interactions (7). Right: kinetic distribution in the phase space.…”

Section: Test 3: Boltzmann Vs Hydrodynamics For D =mentioning

confidence: 99%

“…More recently, also the direct link between follow-the-leader microscopic models and the Aw-Rascle macroscopic model has been explored. In particular, in [9,10] the authors prove that the trajectories of the former converge, in the 1-Wasserstein metric, to the unique entropy solution of the latter when a suitable large particle limit is considered. Their strategy consists in interpreting the follow-the-leader model as a discrete Lagrangian approximation of the target macroscopic model.…”

Section: Introductionmentioning

confidence: 99%

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The Aw–Rascle Traffic Model: Enskog-Type Kinetic Derivation and Generalisations

Dimarco

Tosin

2019

J Stat Phys

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We study the derivation of second order macroscopic traffic models from kinetic descriptions. In particular, we recover the celebrated Aw-Rascle model as the hydrodynamic limit of an Enskog-type kinetic equation out of a precise characterisation of the microscopic binary interactions among the vehicles. Unlike other derivations available in the literature, our approach unveils the multiscale physics behind the Aw-Rascle model. This further allows us to generalise it to a new class of second order macroscopic models complying with the Aw-Rascle consistency condition, namely the fact that no wave should travel faster than the mean traffic flow.

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Section: Boltzmann-type Model With and Without Stochasticitymentioning

confidence: 99%

Section: Test 3: Boltzmann Vs Hydrodynamics For D =mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The Aw–Rascle Traffic Model: Enskog-Type Kinetic Derivation and Generalisations

Dimarco

Tosin

2019

J Stat Phys

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“…where f (ρ) = ρv(ρ), (1.12) has been studied in various papers [18,25,26]. For the nonlocal model (1.1), existence of entropy weak solutions for the Cauchy problem was proved in [9] by utilizing the convergence of a finite difference scheme, and in [24] by means of a finite volume scheme.…”

Section: Introductionmentioning

confidence: 99%

Traveling waves for nonlocal models of traffic flow

Ridder

Shen²

2019

Discrete &Amp; Continuous Dynamical Systems - A

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We consider several non-local models for traffic flow, including both microscopic ODE models and macroscopic PDE models. The ODE models describe the movement of individual cars, where each driver adjusts the speed according to the road condition over an interval in the front of the car. These models are known as the FtLs (Follow-the-Leaders) models. The corresponding PDE models, describing the evolution for the density of cars, are conservation laws with non-local flux functions. For both types of models, we study stationary traveling wave profiles and stationary discrete traveling wave profiles. (See definitions 1.1 and 1.2, respectively.) We derive delay differential equations satisfied by the profiles for the FtLs models, and delay integro-differential equations for the traveling waves of the nonlocal PDE models. The existence and uniqueness (up to horizontal shifts) of the stationary traveling wave profiles are established. Furthermore, we show that the traveling wave profiles are time asymptotic limits for the corresponding Cauchy problems, under mild assumptions on the smooth initial condition. w(y − z i (t)) dy, k ≥ 0, 1, 2, · · · .(1.8)Notice that the summation in (1.7) actually contains only finitely many non-zero terms. Indeed, if (m + 1) ≥ h, then for every k > m one hasHence, by (1.3), w i,k = 0. With the above definition, from (1.3) it also follows m k=0 w i,k (t) = 1, w i,k (t) ≥ 0 ∀t ≥ 0.(1.9)

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“…Aw et al [1], Greenberg [28], and Di Francesco et al [17] investigated the many-particle limit in the framework of second-order traffic models, deriving the macroscopic Aw-Rascle-Zhang (ARZ) model [2,51] from a particular second-order microscopic follow-the-leader (FtL) model [30,43]. Instead Colombo and Rossi [9], Rossi [47], Di Francesco and Rosini [18], and Di Francesco et al [16] investigated the many-particle limit in the framework of first-order traffic models, deriving the macroscopic Lighthill-Whitham-Richards (LWR) model [39,45] as the limit of a first-order FtL model. Let us also mention the papers by Forcadel et al [24], Forcadel and Salazar [23] which investigate the many-particle limit exploiting the link between conservation laws and Hamilton-Jacobi equations.…”

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confidence: 99%

An interface-free multi-scale multi-order model for traffic flow

Cristiani¹,

Iacomini²

2019

Discrete &Amp; Continuous Dynamical Systems - B

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In this paper we present a new multi-scale method for reproducing traffic flow which couples a first-order macroscopic model with a second-order microscopic model, avoiding any interface or boundary conditions between them. The multi-scale model is characterized by the fact that microscopic and macroscopic descriptions are not spatially separated. On the contrary, the macro-scale is always active while the micro-scale is activated only if needed by the traffic conditions. The Euler-Godunov scheme associated to the model is conservative and it is able to reproduce typical traffic phenomena like stop & go waves.

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Rigorous Derivation of Nonlinear Scalar Conservation Laws from Follow-the-Leader Type Models via Many Particle Limit

Cited by 84 publications

References 51 publications

The Aw–Rascle Traffic Model: Enskog-Type Kinetic Derivation and Generalisations

The Aw–Rascle Traffic Model: Enskog-Type Kinetic Derivation and Generalisations

Traveling waves for nonlocal models of traffic flow

An interface-free multi-scale multi-order model for traffic flow

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