Simulation-Based Connected and Automated Vehicle Models on Highway Sections: A Literature Review

This study provides a literature review of the simulation-based connected and automated intelligent-vehicle studies. Media and car-manufacturing companies predict that connected and automated vehicles (CAVs) would be available in the near future. However, society and transportation systems might not be completely ready for their implementation in various aspects, e.g., public acceptance, technology, infrastructure, and/or policy. Since the empirical field data for CAVs are not available at present, many researchers develop micro or macro simulation models to evaluate the CAV impacts. This study classifies the most commonly used intelligent-vehicle types into four categories (i.e., adaptive cruise control, ACC; cooperative adaptive cruise control, CACC; automated vehicle, AV; CAV) and summarizes the intelligent-vehicle car-following models (i.e., Intelligent Driver Model, IDM; MICroscopic Model for Simulation of Intelligent Cruise Control, MIXIC). The review results offer new insights for future intelligent-vehicle analyses: (i) the increase in the market-penetration rate of intelligent vehicles has a significant impact on traffic flow conditions; (ii) without vehicle connections, such as the ACC vehicles, the roadway-capacity increase would be marginal; (iii) none of the parameters in the AV or CAV models is calibrated by the actual field data; (iv) both longitudinal and lateral movements of intelligent vehicles can reduce energy consumption and environmental costs compared to human-driven vehicles; (v) research gap exists in studying the car-following models for newly developed intelligent vehicles; and (vi) the estimated impacts are not converted into a unified metric (i.e., welfare economic impact on users or society) which is essential to evaluate intelligent vehicles from an overall societal perspective.

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A Review of Car-Following Models and Modeling Tools for Human and Autonomous-Ready Driving Behaviors in Micro-Simulation

Smart Cities ◽

10.3390/smartcities4010019 ◽

2021 ◽

Vol 4 (1) ◽

pp. 314-335

Author(s):

Hafiz Usman Ahmed ◽

Ying Huang ◽

Pan Lu

Keyword(s):

Autonomous Vehicles ◽

Adaptive Cruise Control ◽

Cruise Control ◽

Modeling Tools ◽

Microscopic Traffic Simulation ◽

Simulation Tools ◽

Car Following ◽

Driving Behaviors ◽

Micro Simulation ◽

Models And Modeling

The platform of a microscopic traffic simulation provides an opportunity to study the driving behavior of vehicles on a roadway system. Compared to traditional conventional cars with human drivers, the car-following behaviors of autonomous vehicles (AVs) and connected autonomous vehicles (CAVs) would be quite different and hence require additional modeling efforts. This paper presents a thorough review of the literature on the car-following models used in prevalent micro-simulation tools for vehicles with both human and robot drivers. Specifically, the car-following logics such as the Wiedemann model and adaptive cruise control technology were reviewed based on the vehicle’s dynamic behavior and driving environments. In addition, some of the more recent “AV-ready (autonomous vehicles ready) tools” in micro-simulation platforms are also discussed in this paper.

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Evaluation of Driver Car-Following Behavior Models for Cooperative Adaptive Cruise Control Systems

Transportation Research Record Journal of the Transportation Research Board ◽

10.3141/2622-08 ◽

2017 ◽

Vol 2622 (1) ◽

pp. 84-95 ◽

Cited By ~ 6

Author(s):

Mizanur Rahman ◽

Mashrur Chowdhury ◽

Kakan Dey ◽

M. Rafiul Islam ◽

Taufiquar Khan

Keyword(s):

Vehicle Dynamics ◽

Adaptive Cruise Control ◽

User Acceptance ◽

Evaluation Framework ◽

Cruise Control ◽

String Stability ◽

Maximum Acceleration ◽

Car Following ◽

Cooperative Adaptive Cruise Control ◽

Behavior Models

A cooperative adaptive cruise control (CACC) system targeted to obtain a high level of user acceptance must replicate the driving experience in each CACC vehicle without compromising the occupant’s comfort. “User acceptance” can be defined as the safety and comfort of the occupant in the CACC vehicle in terms of acceptable vehicle dynamics (i.e., the maximum acceleration or deceleration) and string stability (i.e., the fluctuations in the vehicle’s position, speed, and acceleration). The primary objective of this study was to develop an evaluation framework for the application of a driver car-following behavior model in CACC system design to ensure user acceptance in terms of vehicle dynamics and string stability. The authors adopted two widely used driver car-following behavior models, ( a) the optimum velocity model (OVM) and ( b) the intelligent driver model (IDM), to prove the efficacy of the evaluation framework developed in this research for CACC system design. A platoon of six vehicles was simulated for three traffic flow states (uniform speed, speed with constant acceleration, and speed with constant deceleration) with different acceleration and deceleration rates. The maximum acceleration or deceleration and the sum of the squares of the errors of the follower vehicle speed were measured to evaluate user acceptance in terms of vehicle dynamics and string stability. Analysis of the simulation results revealed that the OVM performed better at modeling a CACC system than did the IDM in terms of acceptable vehicle dynamics and string stability.

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Linear Acceleration Car-Following Model Development and Validation

Transportation Research Record Journal of the Transportation Research Board ◽

10.3141/1644-02 ◽

1998 ◽

Vol 1644 (1) ◽

pp. 10-19 ◽

Cited By ~ 24

Author(s):

M.F. Aycin ◽

R.F. Benekohal

Keyword(s):

Intelligent Transportation Systems ◽

Field Data ◽

Statistical Tests ◽

Reaction Times ◽

Linear Acceleration ◽

Transportation Systems ◽

Cruise Control ◽

Vehicle Simulation ◽

Car Following ◽

Car Following Model

A linear acceleration car-following model has been developed for realistic simulation of traffic flow in intelligent transportation systems (ITS) applications. The new model provides continuous acceleration profiles instead of the stepwise profiles that are currently used. The brake reaction times of the drivers are simulated effectively and are independent of the simulation time steps. Chain-reaction times of the drivers are also simulated and perception thresholds are incorporated in the model. The preferred time headways are utilized to determine the simulated drivers’ separation during car-following. The features of the model and the realistic vehicle simulation in car-following and in stop-and-go conditions make this model suitable to ITS, especially to autonomous intelligent cruise-control systems. The car-following algorithm is validated at microscopic and macroscopic levels by using field data. Simulated versus field trajectories and statistical tests show very strong agreement between simulation results and field data.

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