Dynamic motion planner with trajectory optimisation for automated highway lane‐changing driving

Liu, Xiao; Liang, Jun; Zhang, Hua

doi:10.1049/iet-its.2020.0465

Cited by 8 publications

(7 citation statements)

References 31 publications

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Section: Data Preprocessingmentioning

confidence: 99%

“…Extracting complete lane changing and lane keeping samples from datasets is the basis of identifying driving intention accurately. In this section, taking the extraction of complete left and right lane changing and lane keeping data samples from NGSIM‐I80 dataset as an example, the steps of data preprocessing are described as follows [33, 34]: Step 1. Select the vehicle trajectory data with vehicle type of car in I‐80 original dataset, and eliminate the vehicle trajectory data with vehicle type of motorcycle and truck. Step 2.…”

Section: Data Preprocessing and Model Trainingmentioning

confidence: 99%

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Dynamic driving intention recognition of vehicles with different driving styles of surrounding vehicles

Zhang

Liang

2021

IET Intelligent Trans Sys

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Driving behaviour of surrounding vehicles have impacts on the security of ego vehicle. However, many vehicles do not use the turn signal in advance as a warning when changing lanes, which often leads to traffic accidents. Therefore, in the case of Internet of Vehicles (IoV) technology has not been popularized, recognizing the driving intention of surrounding vehicles timely and accurately through effective method is of great significance to ego vehicle. In this paper, a dynamic driving intention recognition method for surrounding vehicles based on adaptive multi‐dimension continuous Gaussian mixture‐HMM (AMCGM‐HMM) is proposed. Considering that driving styles of surrounding vehicles are different, a feature‐based multi‐dimensional time series clustering algorithm is adopted to cluster the lane changing data samples and the results are used as the input of AMCGM‐HMM. Parameters that may affect the recognition accuracy are optimized by multi‐objective particle swarm optimization (MOPSO) algorithm to realize the adaptive of the method. The proposed method is verified on NGSIM dataset, and the application of this model is tested on the PreScan simulation platform combined with adaptive cruise control (ACC) system. Experimental results show that the proposed method can identify the driving intention of surrounding vehicles in advance and has high accuracy.

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Section: Data Preprocessingmentioning

confidence: 99%

Section: Data Preprocessing and Model Trainingmentioning

confidence: 99%

Dynamic driving intention recognition of vehicles with different driving styles of surrounding vehicles

Zhang

Liang

2021

IET Intelligent Trans Sys

Self Cite

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“…The global path planning module generates a macroscopic path based on the start and end points, but it does not take into account the real-time environment of certain vehicles. The local route planning module of the automated vehicle generates a route with traffic and avoidance functions based on real-time environment information for the control module to follow [7][8][9].…”

Section: Introductionmentioning

confidence: 99%

A Review of the Motion Planning and Control Methods for Automated Vehicles

Gao

Ding

et al. 2023

Sensors

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The motion planning and control method of automated vehicles, as the key technology of automated vehicles, directly affects the safety, comfort, and other technical indicators of vehicles. The planning module is responsible for generating a vehicle driving path. The control module is responsible for driving the vehicle. In this study, we review the main methods and achievements in motion planning and motion control for automated vehicles. The advantages and disadvantages of various planning and control methods are comparatively analyzed. Finally, some predictions and summaries based on the existing research results and trends are proposed. Through this analysis, it is believed that various types of algorithms will be further integrated in the future to complement each other’s strengths and weaknesses. The next area of research will be to establish more accurate vehicle models to describe vehicle motion, improve the generalization-solving ability of algorithms, and enhance the planning and control of integrated ‘human-vehicle-road’ traffic systems.

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“…In the backward direction, the strategy and planning results of the ego vehicle also influence the future trajectory of other vehicles, causing the prediction results to vary. Therefore, the models of prediction like [3][4][5], the design of decision-making algorithms [6,7] and the development of planning schemes [8][9][10] should be fully incorporated to realize safe navigation in a dynamic environment.…”

Section: Introductionmentioning

confidence: 99%

Spatio‐temporal decision‐making and trajectory planning framework with flexible constraints in closed‐loop dynamic traffic

Zhang

Liu

et al. 2022

IET Intelligent Trans Sys

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Driving in interactive dynamic traffic is a huge challenge for autonomous vehicles, especially for motion planning. The autonomous vehicle not only needs to predict the future states of the social vehicles to avoid a collision but also realizes the comfort and continuous plan. To deal with the problem, a spatio‐temporal decision‐making and motion planning framework with flexible constraints based on previous work is proposed. Improvements can be highlighted in three aspects. First, a neural network for trajectory prediction is trained and it is integrated into the framework, which can learn the social vehicles' reactions in the negotiation better and give more accurate predictions. Second, instead of setting the fixed local targets, the flexible‐constraint mechanism is introduced to increase the success rate of continuous planning, specifically, the local planning target is determined conditioned on the situation with an elastic factor. Third, two popular simulators with randomly disposed traffic participants are exploited, where vehicles are mutually influenced, more similar to real‐world traffic. The closed‐loop tests with zero crashes and the comparative experiments with traditional models demonstrate the superior performance and practical significance of the proposed framework.

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Dynamic motion planner with trajectory optimisation for automated highway lane‐changing driving

Cited by 8 publications

References 31 publications

Dynamic driving intention recognition of vehicles with different driving styles of surrounding vehicles

Dynamic driving intention recognition of vehicles with different driving styles of surrounding vehicles

A Review of the Motion Planning and Control Methods for Automated Vehicles

Spatio‐temporal decision‐making and trajectory planning framework with flexible constraints in closed‐loop dynamic traffic

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