Trajectory Tracking Control Algorithm for Autonomous Vehicle Considering Cornering Characteristics

Cao, Jingwei; Song, Chuanxue; Peng, Silun; Song, Shenmin; Zhang, Xu; Xiao, Feng

doi:10.1109/access.2020.2982963

Cited by 53 publications

(20 citation statements)

References 39 publications

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“…Furthermore, results focusing on tracking-while-driving problems may opt for a vehicle behavior model, or a kinematic model, as opposed to one that is based on appearance criteria. Examples of such approaches are [75][76][77], where the authors build models of vehicle behavior from parameters such as steering angles, headings, offset distances, and relative positions. Note that kinematic and motion models are generally more suited to situations where the input consists in data from radar, Light Detection and Ranging (LiDAR) or Global Positioning Systems (GPS), as opposed to image sequences.…”

Section: Traditional Algorithms and Methods Focusing On High-performancementioning

confidence: 99%

“…-traditional, classic methods do not model sequence dependencies as effectively as many RNN-based solutions Models that represent and predict actor relationships using flow-networks and graphs [83,85,89,90] Models relying on geometric representations, kinematics and pose estimations [74,75,77,91] Models that ensure detection coherence using adaptive partitioning of the problem space [71,86] Methods relying on Markov models and Markov decision processes [66][67][68] Methods that build appearance models and/or use appearance similarity metrics [72,73,87,88] Methods using a multi-stage tracking pipeline incorporating filtering, segmentation, clustering and/or data association [76,78] Methods relying on lightweight filtering and optimization for high-speed high-performance applications [63,64,80,84]…”

Section: Strengthsmentioning

confidence: 99%

See 1 more Smart Citation

A Review of Tracking and Trajectory Prediction Methods for Autonomous Driving

2021

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This paper provides a literature review of some of the most important concepts, techniques, and methodologies used within autonomous car systems. Specifically, we focus on two aspects extensively explored in the related literature: tracking, i.e., identifying pedestrians, cars or obstacles from images, observations or sensor data, and prediction, i.e., anticipating the future trajectories and motion of other vehicles in order to facilitate navigating through various traffic conditions. Approaches based on deep neural networks and others, especially stochastic techniques, are reported.

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Section: Traditional Algorithms and Methods Focusing On High-performancementioning

confidence: 99%

Section: Strengthsmentioning

confidence: 99%

A Review of Tracking and Trajectory Prediction Methods for Autonomous Driving

2021

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“…The demands of traffic safety as well as the advances in sensing technology arouse researchers’ attention on autonomous vehicles and facilitate the development of this field [ 1 , 2 ]. Vehicle motion control is a key technology in autonomous vehicles, as it has a direct effect on tracking performance and safety [ 3 ]. This paper is concerned with the path tracking control of autonomous vehicles, which aims at ensuring the vehicle to accurately follow a reference trajectory and maintain stability under varying environmental and vehicular conditions.…”

Section: Introductionmentioning

confidence: 99%

Preview Control with Dynamic Constraints for Autonomous Vehicles

Ouyang

Cui

et al. 2021

Sensors

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In this paper, a preview theory-based steering control approach considering vehicle dynamic constraints is presented. The constrained variables are predicted by an error states system and utilized to adjust the control law once the established dynamic constraints are violated. The simulated annealing optimization algorithm for preview length is conducted to improve the adaptability of the controller to varying velocities and road adhesion coefficients. The theoretical stability of a closed-loop system is guaranteed using Lyapunov theory, and further analysis of the system response in time domain and frequency domain is discussed. The results of simulations implemented on Carsim–Simulink demonstrate the favorable performance of the proposed control in tracking accuracy and system stability under extreme conditions.

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“…In addition, many MPC algorithms for autonomous driving use linear predictive models based on approximate linearization [16]. A linear time-varying predictive model considering cornering characteristics was designed and optimized in [17]. Gallep et al directly used a simplified vehicle linear kinematics model and verified the algorithm by a single-shift simulation [18].…”

Section: Introductionmentioning

confidence: 99%

Research for Nonlinear Model Predictive Controls to Laterally Control Unmanned Vehicle Trajectory Tracking

et al. 2020

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The autonomous driving is rapid developing recently and model predictive controls (MPCs) have been widely used in unmanned vehicle trajectory tracking. MPCs are advantageous because of their predictive modeling, rolling optimization, and feedback correction. In recent years, most studies on unmanned vehicle trajectory tracking have used only linear model predictive controls to solve MPC algorithm shortcomings in real time. Previous studies have not investigated problems under conditions where speeds are too fast or trajectory curvatures change rapidly, because of the poor accuracy of approximate linearization. A nonlinear model predictive control optimization algorithm based on the collocation method is proposed, which can reduce calculation load. The algorithm aims to reduce trajectory tracking errors while ensuring real-time performance. Monte Carlo simulations of the uncertain systems are carried out to analyze the robustness of the algorithm. Hardware-in-the-loop simulation and actual vehicle experiments were also conducted. Experiment results show that under i7-8700, the calculation time is less than 100 ms, and the mean square error of the lateral deviation is maintained at 10−3 m2, which proves the proposed algorithm can meet the requirement of real time and accuracy in some particular situations. The unmanned vehicle trajectory tracking method provided in this article can meet the needs of real-time control.

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Trajectory Tracking Control Algorithm for Autonomous Vehicle Considering Cornering Characteristics

Cited by 53 publications

References 39 publications

A Review of Tracking and Trajectory Prediction Methods for Autonomous Driving

A Review of Tracking and Trajectory Prediction Methods for Autonomous Driving

Preview Control with Dynamic Constraints for Autonomous Vehicles

Research for Nonlinear Model Predictive Controls to Laterally Control Unmanned Vehicle Trajectory Tracking

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