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JACIII Vol.29 No.4 pp. 921-930
doi: 10.20965/jaciii.2025.p0921
(2025)

Research Paper:

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Dynamic Sampling and Control for Automated Road Pre-Marking Robot

Meng Wang*1 ORCID Icon, Shiyun Zhu*2,† ORCID Icon, Juexuan Chen*2 ORCID Icon, Yutong Lu*3 ORCID Icon, Lang Zhu*4, and Xue Lv*1 ORCID Icon

*1Changjiang Institute of Technology
No.9 Wenhua Avenue, Jiangxia District, Wuhan, Hubei 430212, China

*2Wuhan Goyu Intelligence Technology Co., Ltd.
No.1 Fenghuang Yuan 3rd Road, East Lake High-tech Development Zone, Wuhan, Hubei 430200, China

Corresponding author

*3Department of Economics & Department of Statistics, University of Toronto
1080 Bay Street, Toronto, Ontario M, Canada

*4Roadiant (Suzhou) intelligent Technology Co., Ltd.
No.2266 Taiyang Road, Xiangcheng District, Suzhou, Jiangsu 215100, China

Received:
December 28, 2024
Accepted:
April 13, 2025
Published:
July 20, 2025
Creative Commons License
Keywords:
road lane line, pre-marking robot, autonomous navigation, curvature-adaptive pure pursuit control, dynamic point sampling
Abstract

This study introduces a specialized pre-marking robotic system that boasts a high degree of autonomy in response to low efficiency and inaccuracy in pre-marking operations for road delineations on newly constructed roads. The system is designed for autonomous navigation and precise spray-painting of road markings. It employs dynamic point sampling technology, enabling continuous and real-time acquisition of road coordinate information, thereby significantly improving pre-marking efficiency. A three-point circle correction method is implemented to generate the robot’s target path that includes curvature information. A curvature-adaptive pure pursuit control strategy is executed to ensure high-precision tracking of the pre-marking robot along the target path. Simulation experiments have confirmed the effectiveness and reliability of the robotic system. Practical applications reveal a marking error of less than 1.5 cm in long curved road scenario and 2 cm in right-angle curve road scenario. This result achieves efficient and accurate pre-marking operations and provides substantial technical support for road construction and maintenance.

Manual sampling and robotic line drawing

Manual sampling and robotic line drawing

Cite this article as:
M. Wang, S. Zhu, J. Chen, Y. Lu, L. Zhu, and X. Lv, “Dynamic Sampling and Control for Automated Road Pre-Marking Robot,” J. Adv. Comput. Intell. Intell. Inform., Vol.29 No.4, pp. 921-930, 2025.
Data files:
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Last updated on Jul. 19, 2025