Analytical Prediction of Self-Organized Traffic Jams as a Function of Increasing ACC Penetration

Jerath, Kshitij; Brennan, Sean

doi:10.1109/tits.2012.2217742

Cited by 60 publications

(26 citation statements)

References 21 publications

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“…Intersections are usually the most congested places [14], and two intersections are chosen for the analysis. The third section is chosen because it is connected with SR167, and the traffic is more congested.…”

Section: Road Selectionmentioning

confidence: 99%

Modeling and simulations on automated vehicles to alleviate traffic congestion

Chang¹,

Wang²,

Xiao³

et al. 2017

Math. models, eng.

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Abstract. Automated vehicle technologies have the potential to improve traffic efficiency, stability and safety. Some models of mixed traffic are presented, which consist of automated vehicles and regular vehicles. First, a differential equation model based on automated vehicles is developed by regarding the traffic flow as a whole and using three continuous variables (traffic density, driving speed and traffic volume) to reflect the basic characteristics of traffic from the macroscopic perspective. Second, by taking into account (1) Actual Expected Speed Ratio (AESR), (2) Change Lane Count (CL), (3) Backward Distance (BD), and (4) Over Take (OT), the traffic flow evaluation model is established. Furthermore, by selecting locations randomly, we take the average value of the five cellular automata to the simulating results and validate the reliability of the model in the tolerance. Finally, optimal solutions to accommodate automated vehicles are given.

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Section: Road Selectionmentioning

confidence: 99%

Modeling and simulations on automated vehicles to alleviate traffic congestion

Chang¹,

Wang²,

Xiao³

et al. 2017

Math. models, eng.

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show abstract

“…In the U.S., about $78.2 billion is annually wasted as a result of road traffic congestion [1][2][3][4]. Lost productivity, resources, time, gas, etc., are examples of undesirable consequences of road traffic congestion.…”

Section: Introductionmentioning

confidence: 99%

“…[14,15]. Adaptive cruise control (ACC), advanced driver-assistance systems (ADASs), variable speed limits (VSLs)/variable speed signs (VSSs), ramp metering, and dynamic cruise control (DCC), etc., are the existing mechanisms used to ensure safety, efficiency, and effective utilization of vehicle gas, as the main goals of ITS [3,6,10,11,[14][15][16][17][18]. Static traffic controls (foreseen and predictable) and dynamic traffic controls (unforeseen and unpredictable) are congestion control mechanisms currently in use [17].…”

Section: Introductionmentioning

confidence: 99%

On an efficient and effective Intelligent Transportation System (ITS) using field and simulation data

Ekedebe

Chen

et al. 2014

SPIE Proceedings

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Intelligent transportation system (ITS) applications are expected to provide a more efficient, effective, reliable, and safe driving experience, which can minimize road traffic congestion resulting in a better traffic flow management. To efficiently manage traffic flows, in this paper, we compare the effectiveness of two well-known vehicle routing algorithms: the Dijkstra's shortest path algorithm and the A * (Astar) algorithm in terms of the total travel time and the travel distance. To this end, we built a generic ITS test-bed and created several real-world driving scenarios using field and simulation data to evaluate the performance of these two routing algorithms. The dataset used in our simulation is six weeks traffic volume data from 08/01/2012 to 09/27/2012 in the Maryland (MD)/Washington DC and Virginia (VA) area. Our simulation data shows that an increase in network size results in scalability problems as the efficiency and effectiveness of these algorithms diminishes in larger road networks with greater traffic volume densities, flow rates, and congested conditions. In addition, the imprecision of the road network increases as the network size and the traffic volume density increases. Our study shows that the ability of these vehicular routing algorithms to adaptively route traffic depends on the size and type of road networks, and the current roadway conditions.

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“…Congestion which cannot be traced to a bottleneck is often referred to as a selforganized or "phantom" jam and occurs when the critical threshold of vehicle density is exceeded (Sugiyamal et al, 2008). Jerath and Brennan (2012) show both that the traffic density (vehicles per unit distance) at which congestion criticality is reached is higher in a fleet of adaptive cruise control (ACC) equipped vehicles and that adding non-ACC vehicles to the fleet, where humans are responsible for longitudinal control (acceleration and deceleration), increases the likelihood of a phantom jam. One may therefore conclude that driver reaction time and subsequent overreaction to a braking stimulus is a key contributing factor to triggering a phantom jam (Zielke et al, 2008).…”

Section: Congestionmentioning

confidence: 99%

“…At the leading edge of automobile technology are autonomous vehicle projects by Audi, BMW, Daimler, Ford, GM, Google, Nissan, Toyota, Volvo, and others that aim to reduce human driver fallibility (Knight, 2013), but general availability and widespread adoption is many years away not only due to a patchwork of regulatory frameworks (Kalra et al, 2009;Lassa, 2013) but also because the current cost of technology for a fully autonomous vehicle significantly exceeds the cost of an average vehicle (Rebsamen et al, 2012;Litman, 2013). Additionally, autonomous vehicles in a heterogeneous fleet will only be able to drive as efficiently as (though more safely than) the human-controlled vehicles around them (Jerath and Brennan, 2012 (Ma et al, 2012). However, that particular computer model required a very high percentage of adoption in order to realize overall improved flow and environmental benefit (Ma et al, 2012).…”

Section: Solutionsmentioning

confidence: 99%

Counteracting traffic congestion using intelligent driver feedback

Drum¹

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Analytical Prediction of Self-Organized Traffic Jams as a Function of Increasing ACC Penetration

Cited by 60 publications

References 21 publications

Modeling and simulations on automated vehicles to alleviate traffic congestion

Modeling and simulations on automated vehicles to alleviate traffic congestion

On an efficient and effective Intelligent Transportation System (ITS) using field and simulation data

Counteracting traffic congestion using intelligent driver feedback

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