Loading [a11y]/accessibility-menu.js
A Safe Motion Planning and Reliable Control Framework for Autonomous Vehicles | IEEE Journals & Magazine | IEEE Xplore
Access provided by:
MIT Libraries
Sign Out
Access provided by:
MIT Libraries
Sign Out
ADVANCED SEARCH
Journals & Magazines >IEEE Transactions on Intellig... >Volume: 9 Issue: 4

A Safe Motion Planning and Reliable Control Framework for Autonomous Vehicles

PDF
Huihui Pan; Mao Luo; Jue Wang; Tenglong Huang; Weichao Sun
All Authors

Abstract:

Accurate trajectory tracking is unrealistic in real-world scenarios, however, which is commonly assumed to facilitate motion planning algorithm design. In this paper, a s...Show More

Metadata

Abstract:

Accurate trajectory tracking is unrealistic in real-world scenarios, however, which is commonly assumed to facilitate motion planning algorithm design. In this paper, a safe and reliable motion planning and control framework is proposed to handle the tracking errors caused by inaccurate tracking by coordinating the motion planning layer and controller. Specifically, motion space is divided into safe regions and risky regions by designing the movement restraint size dependent on tracking error to construct the repulsive potential field. The collision-free waypoint set can then be obtained by combining global search and the proposed waypoint set filtering method. The planned trajectory is fitted by an optimization-based approach which minimizes the acceleration of the reference trajectory. Then, the planned trajectory is checked and modified by the designed anti-collision modification to ensure safety. Using invertible transformation and adaptive compensation allows the transient trajectory tracking errors to be limited within the designed region even with actuator faults. Because tracking error is considered and margined at the planning level, safety and reliability can be guaranteed by the coordination between the planning and control levels under inaccurate tracking and actuator faults. The advantages and effectiveness of the proposed motion planning and control method are verified by simulation and experimental results.
Published in: IEEE Transactions on Intelligent Vehicles ( Volume: 9, Issue: 4, April 2024)
Page(s): 4780 - 4793
Date of Publication: 31 January 2024

ISSN Information:

DOI: 10.1109/TIV.2024.3360418

Funding Agency:

References is not available for this document.
Contents

I. Introduction

Autonomous vehicles [1], including autonomous robot vehicles [2], unmanned vehicles [3], and surface vehicles [4], performing a basic navigation task generally require perception, motion planning, and control to work together [3], [5]. The motion planning [6], [7], [8], [9] layer is taken as the brain, which processes the perception information obtained from sensors to generate a safe motion or trajectory without collisions. The control level [10] designs a suitable controller to track the desired motion or trajectory. To simplify motion planning algorithm design, it is commonly assumed that the planned trajectory can be tracked with complete accuracy [11]. Because tracking errors caused by inaccurate tracking are difficult to obtain in advance, it leads to collision risk caused by tracking errors in the planning layer that are hard to avoid. In this paper, it is expected to design a motion planning and control scheme that allows the system to be safe and collision-free under inaccurate tracking by coordinating motion control and planning algorithms in the presence of tracking errors.

Select All
1.
S. Park and S. Hashimoto, "Autonomous mobile robot navigation using passive RFID in indoor environment", IEEE Trans. Ind. Electron., vol. 56, no. 7, pp. 2366-2373, Jul. 2009.
View Article
Google Scholar
2.
D. Dolgov, S. Thrun, M. Montemerlo and J. Diebel, "Path planning for autonomous vehicles in unknown semi-structured environments", Int. J. Robot. Res., vol. 29, no. 5, pp. 485-501, 2010.
CrossRef Google Scholar
3.
D. Cao et al., "Future directions of intelligent vehicles: Potentials possibilities and perspectives", IEEE Trans. Intell. Veh., vol. 7, no. 1, pp. 7-10, Mar. 2022.
View Article
Google Scholar
4.
D. K. M. Kufoalor, T. A. Johansen, E. F. Brekke, A. Hepsø and K. Trnka, "Autonomous maritime collision avoidance: Field verification of autonomous surface vehicle behavior in challenging scenarios", J. Field Robot., vol. 37, no. 3, pp. 387-403, 2020.
CrossRef Google Scholar
5.
F.-Y. Wang et al., "Verification and validation of intelligent vehicles: Objectives and efforts from China", IEEE Trans. Intell. Veh., vol. 7, no. 2, pp. 164-169, Jun. 2022.
View Article
Google Scholar
6.
F.-Y. Wang, N.-N. Zheng, D. Cao, C. M. Martinez, L. Li and T. Liu, "Parallel driving in CPSS: A unified approach for transport automation and vehicle intelligence", IEEE/CAA J. Automatica Sinica, vol. 4, no. 4, pp. 577-587, Oct. 2017.
View Article
Google Scholar
7.
E. A. Sisbot, L. F. Marin-Urias, R. Alami and T. Simeon, "A human aware mobile robot motion planner", IEEE Trans. Robot., vol. 23, no. 5, pp. 874-883, Oct. 2007.
View Article
Google Scholar
8.
T. Huang, J. Wang and H. Pan, "Adaptive bioinspired preview suspension control with constrained velocity planning for autonomous vehicles", IEEE Trans. Intell. Veh., vol. 8, no. 7, pp. 3925-3935, Jul. 2023.
View Article
Google Scholar
9.
H. Pan, Y. Hong, W. Sun and Y. Jia, "Deep dual-resolution networks for real-time and accurate semantic segmentation of traffic scenes", IEEE Trans. Intell. Transp. Syst., vol. 24, no. 3, pp. 3448-3460, Mar. 2023.
View Article
Google Scholar
10.
F.-Y. Wang, "Parallel control and management for intelligent transportation systems: Concepts architectures and applications", IEEE Trans. Intell. Transp. Syst., vol. 11, no. 3, pp. 630-638, Sep. 2010.
View Article
Google Scholar
11.
L. Chen et al., "Milestones in autonomous driving and intelligent vehicles: Survey of surveys", IEEE Trans. Intell. Veh., vol. 8, no. 2, pp. 1046-1056, Feb. 2023.
View Article
Google Scholar
12.
B. Li et al., "From formula one to autonomous one: History achievements and future perspectives", IEEE Trans. Intell. Veh., vol. 8, no. 5, pp. 3217-3223, May 2023.
View Article
Google Scholar
13.
S. Teng, L. Chen, Y. Ai, Y. Zhou, Z. Xuanyuan and X. Hu, "Hierarchical interpretable imitation learning for end-to-end autonomous driving", IEEE Trans. Intell. Veh., vol. 8, no. 1, pp. 673-683, Jan. 2023.
View Article
Google Scholar
14.
A. J. Rimmer and D. Cebon, "Planning collision-free trajectories for reversing multiply-articulated vehicles", IEEE Trans. Intell. Transp. Syst., vol. 17, no. 7, pp. 1998-2007, Jul. 2016.
View Article
Google Scholar
15.
P. E. Hart, N. J. Nilsson and B. Raphael, "A formal basis for the heuristic determination of minimum cost paths", IEEE Trans. Syst. Sci. Cybern., vol. 4, no. 2, pp. 100-107, Jul. 1968.
View Article
Google Scholar
16.
H. Pan, X. Chang and W. Sun, "Multitask knowledge distillation guides end-to-end lane detection", IEEE Trans. Ind. Inform., vol. 19, no. 9, pp. 9703-9712, Sep. 2023.
View Article
Google Scholar
17.
S. M. Persson and I. Sharf, "Sampling-based A* algorithm for robot path-planning", Int. J. Robot. Res., vol. 33, no. 13, pp. 1683-1708, 2014.
CrossRef Google Scholar
18.
T. Huang, H. Pan, W. Sun and H. Gao, "Sine resistance network-based motion planning approach for autonomous electric vehicles in dynamic environments", IEEE Trans. Transport. Electrific., vol. 8, no. 2, pp. 2862-2873, Jun. 2022.
View Article
Google Scholar
19.
J. Faigl and P. Váňa, "Surveillance planning with bézier curves", IEEE Robot. Automat. Lett., vol. 3, no. 2, pp. 750-757, Apr. 2018.
View Article
Google Scholar
20.
C.-C. Tsai, H.-C. Huang and C.-K. Chan, "Parallel elite genetic algorithm and its application to global path planning for autonomous robot navigation", IEEE Trans. Ind. Electron., vol. 58, no. 10, pp. 4813-4821, Oct. 2011.
View Article
Google Scholar
21.
A. M. Lekkas and T. I. Fossen, "Integral LOS path following for curved paths based on a monotone cubic hermite spline parametrization", IEEE Trans. Control Syst. Technol., vol. 22, no. 6, pp. 2287-2301, Nov. 2014.
View Article
Google Scholar
22.
J. Wittmann and D. J. Rixen, "Time-optimization of trajectories using zero-clamped cubic splines and their analytical gradients", IEEE Robot. Automat. Lett., vol. 7, no. 2, pp. 4528-4534, Apr. 2022.
View Article
Google Scholar
23.
D. Mellinger and V. Kumar, "Minimum snap trajectory generation and control for quadrotors", Proc. IEEE Int. Conf. Robot. Automat., pp. 2520-2525, 2011.
View Article
Google Scholar
24.
A. Piazzi and A. Visioli, "Global minimum-jerk trajectory planning of robot manipulators", IEEE Trans. Ind. Electron., vol. 47, no. 1, pp. 140-149, Feb. 2000.
View Article
Google Scholar
25.
A. D. Ames, X. Xu, J. W. Grizzle and P. Tabuada, "Control barrier function based quadratic programs for safety critical systems", IEEE Trans. Autom. Control, vol. 62, no. 8, pp. 3861-3876, Aug. 2017.
View Article
Google Scholar
26.
A. D. Ames, S. Coogan, M. Egerstedt, G. Notomista, K. Sreenath and P. Tabuada, "Control barrier functions: Theory and applications", Proc. IEEE 18th Eur. Control Conf., pp. 3420-3431, 2019.
View Article
Google Scholar
27.
H. Pan, D. Zhang, W. Sun and X. Yu, "Event-triggered adaptive asymptotic tracking control of uncertain MIMO nonlinear systems with actuator faults", IEEE Trans. Cybern., vol. 52, no. 9, pp. 8655-8667, Sep. 2022.
View Article
Google Scholar
28.
S. L. Herbert, M. Chen, S. Han, S. Bansal, J. F. Fisac and C. J. Tomlin, "FaSTrack: A modular framework for fast and guaranteed safe motion planning", Proc. IEEE 56th Annu. Conf. Decis. Control, pp. 1517-1522, 2017.
View Article
Google Scholar
29.
M. Chen, S. Herbert and C. J. Tomlin, "Exact and efficient Hamilton-Jacobi guaranteed safety analysis via system decomposition", Proc. IEEE Int. Conf. Robot. Automat., pp. 87-92, 2017.
View Article
Google Scholar
30.
G. E. Fainekos, A. Girard, H. Kress-Gazit and G. J. Pappas, "Temporal logic motion planning for dynamic robots", Automatica, vol. 45, no. 2, pp. 343-352, 2009.
CrossRef Google Scholar

Contact IEEE to Subscribe
More Like This
Advancing Autonomous UAV Trajectory Tracking with Compensation for External Actuator Disturbances

2024 4th Interdisciplinary Conference on Electrics and Computer (INTCEC)

Published: 2024

Finite-Time Trajectory Tracking Control of Space Manipulator Under Actuator Saturation

IEEE Transactions on Industrial Electronics

Published: 2020

Show More

References

References is not available for this document.

IEEE Account

Purchase Details

Profile Information

Need Help?

A not-for-profit organization, IEEE is the world's largest technical professional organization dedicated to advancing technology for the benefit of humanity.
© Copyright 2025 IEEE - All rights reserved. Use of this web site signifies your agreement to the terms and conditions.