Tracking vehicle trajectories and fuel rates in phantom traffic jams: Methodology and data

Wu, Frederick Y.; Stern, Raphael; Cui, Shumo; Monache, Maria Laura Delle; Bhadani, Rahul; Bunting, Matt; Churchill, Miles; Hamilton, Nathaniel; Haulcy, R’mani; Piccoli, Benedetto; Seibold, Benjamin; Sprinkle, Jonathan; Work, Daniel B.

doi:10.1016/j.trc.2018.12.012

Cited by 53 publications

(28 citation statements)

References 74 publications

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“…The data used in the calibration were collected from a field car-following experiment that was conducted in the U.S.A. on a circular track of 260 m circumference. For more details, see Wu et al ( 19 ). To calibrate the macroscopic models, the 260 m circuit is divided into 13 cells of equal length of 20 m, and the speed of each cell is extracted every 0.1 s. Data from the time intervals is used, as shown in Table 1.…”

Section: Model Calibration and Validationmentioning

confidence: 99%

“…It was found that traffic instability is caused by the competition between speed adaptation and the cumulative effect of stochastic factors. Other experimental studies also found that each driver's own different responses to similar stimuli might be the source of oscillations in the absence of other interference factors (16)(17)(18)(19). Inspired by the experimental findings, 2D intelligent driver model (IDM) (12,20), 2D optimal velocity model (OVM) (12,21), 2D full velocity difference model (FVDM) (12,22), and desired time gap-brake light model (BLM) (6,23) were developed through considering a 2D stochastic speed-spacing relationship in the original model.…”

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confidence: 93%

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Impact of Stochasticity on Traffic Flow Dynamics in Macroscopic Continuum Models

Zheng

Jiang

Jia

et al. 2020

Transportation Research Record

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Stochasticity is an indispensable factor for describing real traffic situations. Recent experimental study has shown that a model spanning a two-dimensional speed–spacing (or speed–density) relationship has the potential to reproduce the characteristics of traffic flow in both experiments and empirical observations. This paper studies the impact of stochasticity on traffic flow in macroscopic models utilizing the stochastic flow–density relationship. Numerical analysis is conducted under the periodic boundary to study the impact of stochasticity on stability. Traffic flow upstream of a bottleneck is also investigated to study the impact of stochasticity on the oscillation growth feature. It is shown that there is only a quantitative difference for model stability after introducing stochasticity. In contrast, a qualitative change of the traffic oscillation growth feature can be clearly observed. With the introduction of stochasticity, traffic oscillations begin to grow in a concave way along the road. Sensitivity analysis is also performed. It is found that, under the stochastic flow–density relationship: (i) with the decrease of relaxation time, the second-order model becomes stable; (ii) the smaller the propagation speed of small disturbance, the much stronger the traffic oscillation; (iii) the larger the fluctuation range, the sooner the traffic oscillation fully develops; and (iv) the changing probability has trivial impact on the simulation results. Finally, model calibration and validation are conducted. It is shown that the experimental spatiotemporal patterns can be captured by macroscopic models under the stochastic flow–density relationship, especially the second-order model.

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Section: Model Calibration and Validationmentioning

confidence: 99%

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confidence: 93%

Impact of Stochasticity on Traffic Flow Dynamics in Macroscopic Continuum Models

Zheng

Jiang

Jia

et al. 2020

Transportation Research Record

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“…To illustrate the importance of human driving behavior on traffic flow, the seminal work [20] showed experimentally that humancontrolled traffic can exhibit "phantom jams" in which a traffic jam emerges, not from an outside influence such as an accident or lanereduction, but from the collective behavior of drivers. Phantom jams are an important area of traffic control research because they represent a true inefficiency in the flow in which both system throughput is degraded and average fuel efficiency declines [19,26], and frequently arise in non-automated (human) traffic flows [20]. It was subsequently shown [19] that these jams could be effectively "smoothed out" with a single automated vehicle on a ring of 20+ other human drivers.…”

Section: Arxiv:210411267v1 [Eesssy] 22 Apr 2021mentioning

confidence: 99%

Integrated Framework of Vehicle Dynamics, Instabilities, Energy Models, and Sparse Flow Smoothing Controllers

Lee

Gunter

Ramadan

et al. 2021

Proceedings of the Workshop on Data-Driven and Intelligent Cyber-Physical Systems

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“…The video footage recorded during the experiment was processed using image processing algorithms. More details on the image processing algorithms used can be found in the article by Wu, et al [59]. Additionally, vehicle performance data such as fuel consumption was recorded during the experiment using OBDLink MX onboard diagnostics (OBD-II) data loggers.…”

Section: Experimental Designmentioning

confidence: 99%

Feedback Control Algorithms for the Dissipation of Traffic Waves with Autonomous Vehicles

Monache

Liard

Rat

et al. 2019

Computational Intelligence and Optimization Methods for Control Engineering

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This article considers the problem of traffic control in which an autonomous vehicle is used to regulate human piloted traffic to dissipate stop and go traffic waves. We first investigate the controllability of well-known microscopic traffic flow models, namely i) the Bando model (also known as the optimal velocity model), ii) the follow-the-leader model, and iii) a combined optimal velocity follow the leader model. Based on the controllability results, we propose three control strategies for an autonomous vehicle to stabilize the other, human-piloted traffic. We subsequently simulate the control effects on the microscopic models of human drivers in numerical experiments to quantify the potential benefits of the controllers. Based on the simulations, finally we conduct a field experiment with 22 human drivers and a fully autonomous-capable vehicle, to assess the feasibility of autonomous vehicle based traffic control on real human piloted traffic. We show that both in simulation and in the field test that an autonomous vehicle is able to dampen waves generated by 22 cars, and that as a consequence, the total fuel consumption of all vehicles is reduced by up to 20%.

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Tracking vehicle trajectories and fuel rates in phantom traffic jams: Methodology and data

Cited by 53 publications

References 74 publications

Impact of Stochasticity on Traffic Flow Dynamics in Macroscopic Continuum Models

Impact of Stochasticity on Traffic Flow Dynamics in Macroscopic Continuum Models

Integrated Framework of Vehicle Dynamics, Instabilities, Energy Models, and Sparse Flow Smoothing Controllers

Feedback Control Algorithms for the Dissipation of Traffic Waves with Autonomous Vehicles

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