Review and Comparison of Path Tracking Based on Model Predictive Control

Bai, Guoxing; Meng, Yu; Luo, Weidong; Gu, Qing; Liu, Li

doi:10.3390/electronics8101077

Cited by 47 publications

(33 citation statements)

References 66 publications

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“…The motivation of this paper is to facilitate for the SDC path tracker to achieve the previous kind-of-opposing objectives by proposing a sophisticated control methodology that takes into account all these objectives and provide a way to find a delicate balance among them based on the designer preferences. The proposed methodology is based on the Model Predictive Control (MPC) technique due to its flexibility and practicality [10]. The MPC technique is an optimal control method that has the advantage of tailoring its optimization strategy in a way that offers multiple options to reach the desired performance for strongly nonlinear systems with constraints [10], which are difficult to handle using traditional linear control approaches [11].…”

Section: Introductionmentioning

confidence: 99%

“…The proposed methodology is based on the Model Predictive Control (MPC) technique due to its flexibility and practicality [10]. The MPC technique is an optimal control method that has the advantage of tailoring its optimization strategy in a way that offers multiple options to reach the desired performance for strongly nonlinear systems with constraints [10], which are difficult to handle using traditional linear control approaches [11]. http://dx.doi.org/10.12785/ijcds/090511 http://journal.uob.edu.bh Numerous thought-provoking MPC design methodologies exist in the literature, in [12] Ikeda et al proposed a new design of optimal control that takes only specified discrete values and applies finite-horizon sum-ofabsolute-values optimization.…”

Section: Introductionmentioning

confidence: 99%

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Complex Track Maneuvering using Real-Time MPC Control for Autonomous Driving

Farag¹

2020

IJCDS

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Complex Track Maneuvering using Real-Time MPC Control for Autonomous Driving

Farag¹

2020

IJCDS

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“…The most important one is the real-time performance of the controller. The real-time performance of non-linear MPC (NMPC) is inferior [8][9][10], moreover, in [7], the optimisation function has an added dimension due to the increase of the target state. So the method in [7] causes the real-time performance of the controller to deteriorate further.…”

mentioning

confidence: 99%

“…So we also considered other solutions. Considering the advantages of linear MPC (LMPC) in real-time performance [10], we designed a multilayer MPC (MMPC) controller combining NMPC and LMPC [11]. In this controller, the lower LMPC is used to control the robot to track the reference path, while the upper NMPC is used to adjust the longitudinal velocity.…”

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confidence: 99%

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Anti‐sideslip path tracking of wheeled mobile robots based on fuzzy model predictive control

et al. 2020

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When a wheeled mobile robot is travelling at high longitudinal velocities and turning, it may sideslip. Except for a few researchers, this issue has not received much attention. However, there is a high possibility that sideslip may cause danger, so the authors think this problem needs to be solved urgently. The mechanism of preventing sideslip is simple, which is to reduce the longitudinal velocity of the robot when turning. But, how to slow down is a question worth studying. To this end, they have proposed two schemes, but these two schemes have poor real-time performance and poor robustness to positioning errors, respectively. In order to solve the above problems, considering that the real-time and robustness of fuzzy control are very good, they propose a controller by combining robust control and model predictive control in this Letter. The fuzzy control is used to adjust the longitudinal velocity according to the state of the robot, and the model predictive control is used to achieve path tracking. According to the simulation results, the proposed fuzzy model predictive controller does have small errors, small sideslip, good real-time performance, and good robustness to positioning errors.

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Real‐time NMPC path tracker for autonomous vehicles

Farag

2020

Asian Journal of Control

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This work proposes a framework to design, formulate and implement a path tracker for self-driving cars (SDC) based on a nonlinear model-predictive-control (NMPC) approach. The presented methodology is developed to be used by designers in the industrial sector, practitioners, and academics. Therefore, it is straight forward, flexible, and comprehensive. It allows the designer to easily integrate multiple objective terms in the cost function either opposing or correlating. The proposed design of the controller not only targets accurate tracking but also comfortable ride and fast travel time by introducing several sub-objective terms in the main cost function to satisfy these goals. These sub-objective terms are weighted according to their contribution to the optimization problem. The SDC-NMPC framework is developed using the high-performance language C++ and utilizes highly optimized math and optimization libraries for best real-time performance. This makes the SDC-MPC well suited for use in both ADAS and selfdriving cars. Extensive simulation studies featuring complex tracks with many sharp turns have been carried out to evaluate the performance of the proposed SDC-NMPC at different speeds. The presented analysis shows that the proposed controller with its tuning technique outperforms that of the PID-based controller.

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Review and Comparison of Path Tracking Based on Model Predictive Control

Cited by 47 publications

References 66 publications

Complex Track Maneuvering using Real-Time MPC Control for Autonomous Driving

Complex Track Maneuvering using Real-Time MPC Control for Autonomous Driving

Anti‐sideslip path tracking of wheeled mobile robots based on fuzzy model predictive control

Real‐time NMPC path tracker for autonomous vehicles

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