A Research Review on Vehicle Lane Changing Models Considering Intelligent Connected Vehicle and Distracted Driving Behaviours

Purpose The purpose of this study is to effectively optimize vehicle lane-changing behavior and alleviate traffic congestion in ramp area through the study of vehicle lane-changing behaviors in upstream segment of ramp areas. Design/methodology/approach In the upstream segment of ramp areas under a connected vehicle environment, different strategies of vehicle group lane-changing behaviors are modeled to obtain the best group lane-changing strategy. The traffic capacity of roads can be improved by controlling group lane-changing behavior and continuously optimizing lane-changing strategy through connected vehicle technologies. This paper constructs vehicle group lane-changing strategies in upstream segment of ramp areas under a connected vehicle environment. The proposed strategies are simulated by VISSIM. Findings The results show that different lane-changing strategies are modeled through vehicle group in the upstream segment of ramp areas, which can greatly reduce the delay of ramp areas. Originality/value The simulation results verify the validity and rationality of the corresponding vehicle group lane-changing behavior model strategies, effectively standardize the driver's lane-changing behavior, and improve road safety and capacity.

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A Comparative Analysis of Tree-Based Ensemble Methods for Detecting Imminent Lane Change Maneuvers in Connected Vehicle Environments

Transportation Research Record Journal of the Transportation Research Board ◽

10.1177/0361198118780204 ◽

2018 ◽

Vol 2672 (42) ◽

pp. 268-279 ◽

Cited By ~ 8

Author(s):

Saleh R. Mousa ◽

Peter R. Bakhit ◽

Osama A. Osman ◽

Sherif Ishak

Keyword(s):

Gradient Boosting ◽

Lane Change ◽

Connected Vehicle ◽

Classification Problems ◽

Trajectory Data ◽

Modeling Tools ◽

Lane Changing ◽

Extreme Gradient Boosting ◽

Car Crashes ◽

Vehicle Trajectory

Lane changing is one of the main contributors to car crashes in the U.S. The complexity of the decision-making process associated with lane changing makes such maneuvers prone to driving errors, and hence, increases the possibility of car crashes. Thus, researchers have been investigating ways to model and predict lane changing maneuvers for optimally designed crash avoidance systems. Such systems rely on the accuracy of detecting the onset of lane-change maneuvers, which requires comprehensive vehicle trajectory data. Connected Vehicles (CV) data provide opportunities for accurate modeling of lane changing maneuvers, especially with the variety of advanced tools available nowadays. The review of the literature indicates that most of the implemented modeling tools do not achieve reliable accuracy for such critical safety application of lane-change prediction. Recently, eXtreme Gradient Boosting (XGB) became a well-recognized algorithm among the computer science community in solving classification problems due to its accuracy, scalability, and speed. This study implements the XGB in predicting the onset of lane changing maneuvers using CV trajectory data. The performance of XGB is compared to three other tree-based algorithms namely, decision trees, gradient boosting, and random forests. The Next Generation SIMulation trajectory data are used to represent the high-resolution CV data. The results indicate that XGB is superior to the other algorithms with a high accuracy value of 99.7%. This outstanding accuracy is achieved when considering vehicle trajectory data two seconds prior to a potential lane change maneuver. The findings of this study are promising for detection of lane change maneuvers in CV environments.

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Collaborative Strategies and Simulation of Vehicle Group Behaviors for Off-Ramp Areas

Journal of Advanced Transportation ◽

10.1155/2020/8817364 ◽

2020 ◽

Vol 2020 ◽

pp. 1-11

Author(s):

Tong Mo ◽

Keyi Li ◽

Junjie Zhang ◽

Lingqiao Qin ◽

Zhufei Huang ◽

...

Keyword(s):

Traffic Flow ◽

Traffic Accidents ◽

Urban Traffic ◽

Vehicle Group ◽

Connected Vehicle ◽

Lane Changing ◽

Main Road ◽

Flow Balance ◽

Collaborative Strategies ◽

Balance Strategy

With the increase of vehicle ownership and the rapid growth of urban traffic, the problem of congestion in the off-ramp area of the main expressway has become the main factor restricting overall section efficiency and inducing traffic accidents. This paper focuses on the problem of group collaborative lane-changing behaviors of off-ramp vehicles and through vehicles in off-ramp areas and proposes four kinds of vehicle group collaborative strategies based on different road space balance conditions. According to a three-lane expressway scene, a VISSIM-based simulation model is built and the optimization scheme is simulated and evaluated. The simulation results show that with the increase of traffic flow in off-ramp areas, a flow-balance strategy for downstream lanes where off-ramp vehicles merge with the outside lane in advance is more advantageous. When vehicles are leaving the main road, if traffic flow is heavy, the flow-balance strategy for lanes where off-ramp vehicles merge with the outside lane in advance (for example, the proportion of off-ramp vehicles in three lanes is 0 : 0 : 1) is better; otherwise, when the traffic flow on the main road is relatively small, the flow-balance strategy for lanes where off-ramp vehicles are distributed in lanes with different ratios (e.g., 1 : 3 : 6) is better. What is more, for future traffic management in connected vehicle environments, it can be concluded that collaborative vehicle lane-changing strategies with different traffic flow states can help to enhance traffic efficiency.

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Advisory Lane-Changing Assistant at Vehicle Incidents with Connected Vehicles

Transportation Research Record Journal of the Transportation Research Board ◽

10.1177/0361198119849055 ◽

2019 ◽

Vol 2673 (10) ◽

pp. 595-609 ◽

Cited By ~ 3

Author(s):

Hao Yang ◽

Ken Oguchi

Keyword(s):

Sensitivity Analysis ◽

Traffic Congestion ◽

Vehicle Dynamics ◽

Connected Vehicles ◽

Connected Vehicle ◽

Market Penetration ◽

Lane Changing ◽

Lane Changes ◽

Road Congestion ◽

Driving Assistance

Vehicle incidents on roads result in lane closure and severe traffic congestion, and the frequent mandatory lane changes of the upstream vehicles generate capacity drops ahead of the incidents, which further increase road congestion. With the development of connected vehicles, vehicle incidents can be detected by individual vehicles, and immediate driving assistance can be provided to help them pass the incidents efficiently. This paper proposes a distributed lane-changing assistant (DLCA) system with connected vehicles to advise individual vehicles with the optimal lanes to pass incidents with smaller delays. The system introduces connected vehicles to detect the location and the lane closure information of an incident and broadcast the information to the upstream connected vehicles. To determine the optimal lane for each connected vehicle, a speed index is defined for each lane based on the incident information and the downstream connected vehicle dynamics. The DLCA system is evaluated with a microscopic traffic simulator, INTEGRATION, to illustrate its benefits in improving the performance of individual vehicles and mitigating road congestion. A sensitivity analysis of market penetration rates and demand levels of connected vehicles is also conducted in this paper. The results indicate that the DLCA system can reduce the delay by about 22.1% for the connected vehicles, and it has higher benefits on improving the performance of the entire road at higher market penetration rates. In addition, there exists an optimal demand level to maximize the benefits of the system.

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VISSIM-Based Simulation and Analysis of Upstream Segments in Ramp Areas for Optimizing Vehicle Group Lane-Changing Behaviors

Journal of Advanced Transportation ◽

10.1155/2020/5983161 ◽

2020 ◽

Vol 2020 ◽

pp. 1-11

Author(s):

Haijian Li ◽

Zhufei Huang ◽

Xiaofang Zou ◽

Shuo Zheng ◽

Yanfang Yang

Keyword(s):

Traffic Congestion ◽

Road Safety ◽

Vehicle Group ◽

Connected Vehicle ◽

Lane Changing ◽

The Road ◽

Road Capacity ◽

Traffic Capacity ◽

Vehicle Technologies ◽

And Control

The traffic congestion in ramp areas is becoming increasingly prominent. In the upstream segments of ramp areas, effective management and control of lane-changing behaviors can improve the road capacity and make full use of the existing road resource. With the continuous development and application of connected vehicle technologies, lane-changing behaviors can be performed by vehicle groups. Under a connected vehicle environment, the lane-changing behaviors by vehicle groups are controlled in the upstream segment in a ramp area, and the lane-changing behaviors can be completed prior to entering the ramp area. Finally, lane-changing strategies are optimized and identified. VISSIM simulates these proposed strategies. This paper considers the delay as the output index for analyzing and comparing various strategies. The results demonstrate that the delays of different lane-changing strategies are also different. If the delays of ramp areas are to be substantially reduced, it is necessary to continuously optimize the lane-changing strategies by vehicle groups in the upstream segments. This optimization of lane-changing strategies will effectively regulate drivers’ lane-changing behaviors, improve road safety, and increase traffic capacity.

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