Design and Application of Grinding Trajectory Planning Algorithm for Casting Grinding Robot

Xin Wang; Hongbin Ma; Jinyue Bian; Yanhuan Jiang; Yiyi Yin

doi:10.1007/978-981-95-6736-2_43

Design and Application of Grinding Trajectory Planning Algorithm for Casting Grinding Robot

Xin Wang
, Hongbin Ma^*
, Jinyue Bian
, Yanhuan Jiang
, Yiyi Yin

^*Corresponding author for this work

School of Automation

Beijing Institute of Technology
China Aviation Industry Corporation
National Key Lab of Autonomous Intelligent Unmanned Systems

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Grinding is a traditional yet critical process in manufacturing, and the integration of robotic systems can significantly enhance grinding performance while ensuring worker safety. However, current robotic grinding systems primarily rely on manual teaching or offline programming for trajectory generation. Moreover, these methods are often cumbersome and lack scalability. In this paper, a refined trajectory planning approach based on machine vision perception is introduced, aiming to address the issue of limited autonomy in traditional trajectory planning methods. Specifically, for full-surface grinding, a detection algorithm is developed to identify the polishing area on raised, welded and rough surface, enabling precise positioning of the target areas. Two toolpath patterns, a “bow” shape and a “Z” shape, are designed to cover the surface efficiently. For point-by-point polishing, an improved Laplacian matrix is introduced into the Laplacian-Based Contraction pipeline to improve the detection accuracy of key polishing points. The shortest path in the graph is then transferred to 3D space, where a point cloud eight-neighborhood graph is constructed. A minimum spanning tree algorithm is used to simplify the graph, facilitating trajectory sorting and endpoint positioning. The proposed trajectory planning algorithm offers high adaptability to process requirements, including adjustments to grinding head size, depth, angle, path density, and fitting accuracy. Finally, the effectiveness and accuracy of trajectory planning are verified by applying the proposed algorithm to the actual grinding robot.

Original language	English
Title of host publication	Advanced Computational Intelligence and Intelligent Informatics - 9th International Workshop, IWACIII 2025, Proceedings
Editors	Hongbin Ma, Bin Xin, Jinhua She, Shinichi Yoshida
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	602-619
Number of pages	18
ISBN (Print)	9789819567355
DOIs	https://doi.org/10.1007/978-981-95-6736-2_43
Publication status	Published - 2026
Event	9th International Workshop on Advanced Computational Intelligence and Intelligent Informatics, IWACIII 2025 - Zhuhai, China Duration: 31 Oct 2025 → 4 Nov 2025

Publication series

Name	Communications in Computer and Information Science
Volume	2782 CCIS
ISSN (Print)	1865-0929
ISSN (Electronic)	1865-0937

Conference

Conference	9th International Workshop on Advanced Computational Intelligence and Intelligent Informatics, IWACIII 2025
Country/Territory	China
City	Zhuhai
Period	31/10/25 → 4/11/25

Keywords

Machine vision
full surface polishing process
grinding robot
point-by-point polishing process
trajectory planning

Access to Document

10.1007/978-981-95-6736-2_43

Cite this

Wang, X., Ma, H., Bian, J., Jiang, Y., & Yin, Y. (2026). Design and Application of Grinding Trajectory Planning Algorithm for Casting Grinding Robot. In H. Ma, B. Xin, J. She, & S. Yoshida (Eds.), Advanced Computational Intelligence and Intelligent Informatics - 9th International Workshop, IWACIII 2025, Proceedings (pp. 602-619). (Communications in Computer and Information Science; Vol. 2782 CCIS). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-981-95-6736-2_43

Wang, Xin ; Ma, Hongbin ; Bian, Jinyue et al. / Design and Application of Grinding Trajectory Planning Algorithm for Casting Grinding Robot. Advanced Computational Intelligence and Intelligent Informatics - 9th International Workshop, IWACIII 2025, Proceedings. editor / Hongbin Ma ; Bin Xin ; Jinhua She ; Shinichi Yoshida. Springer Science and Business Media Deutschland GmbH, 2026. pp. 602-619 (Communications in Computer and Information Science).

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title = "Design and Application of Grinding Trajectory Planning Algorithm for Casting Grinding Robot",

abstract = "Grinding is a traditional yet critical process in manufacturing, and the integration of robotic systems can significantly enhance grinding performance while ensuring worker safety. However, current robotic grinding systems primarily rely on manual teaching or offline programming for trajectory generation. Moreover, these methods are often cumbersome and lack scalability. In this paper, a refined trajectory planning approach based on machine vision perception is introduced, aiming to address the issue of limited autonomy in traditional trajectory planning methods. Specifically, for full-surface grinding, a detection algorithm is developed to identify the polishing area on raised, welded and rough surface, enabling precise positioning of the target areas. Two toolpath patterns, a “bow” shape and a “Z” shape, are designed to cover the surface efficiently. For point-by-point polishing, an improved Laplacian matrix is introduced into the Laplacian-Based Contraction pipeline to improve the detection accuracy of key polishing points. The shortest path in the graph is then transferred to 3D space, where a point cloud eight-neighborhood graph is constructed. A minimum spanning tree algorithm is used to simplify the graph, facilitating trajectory sorting and endpoint positioning. The proposed trajectory planning algorithm offers high adaptability to process requirements, including adjustments to grinding head size, depth, angle, path density, and fitting accuracy. Finally, the effectiveness and accuracy of trajectory planning are verified by applying the proposed algorithm to the actual grinding robot.",

keywords = "Machine vision, full surface polishing process, grinding robot, point-by-point polishing process, trajectory planning",

author = "Xin Wang and Hongbin Ma and Jinyue Bian and Yanhuan Jiang and Yiyi Yin",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2026.; 9th International Workshop on Advanced Computational Intelligence and Intelligent Informatics, IWACIII 2025 ; Conference date: 31-10-2025 Through 04-11-2025",

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Wang, X, Ma, H, Bian, J, Jiang, Y & Yin, Y 2026, Design and Application of Grinding Trajectory Planning Algorithm for Casting Grinding Robot. in H Ma, B Xin, J She & S Yoshida (eds), Advanced Computational Intelligence and Intelligent Informatics - 9th International Workshop, IWACIII 2025, Proceedings. Communications in Computer and Information Science, vol. 2782 CCIS, Springer Science and Business Media Deutschland GmbH, pp. 602-619, 9th International Workshop on Advanced Computational Intelligence and Intelligent Informatics, IWACIII 2025, Zhuhai, China, 31/10/25. https://doi.org/10.1007/978-981-95-6736-2_43

Design and Application of Grinding Trajectory Planning Algorithm for Casting Grinding Robot. / Wang, Xin; Ma, Hongbin; Bian, Jinyue et al.
Advanced Computational Intelligence and Intelligent Informatics - 9th International Workshop, IWACIII 2025, Proceedings. ed. / Hongbin Ma; Bin Xin; Jinhua She; Shinichi Yoshida. Springer Science and Business Media Deutschland GmbH, 2026. p. 602-619 (Communications in Computer and Information Science; Vol. 2782 CCIS).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Wang, Xin

AU - Ma, Hongbin

AU - Bian, Jinyue

AU - Jiang, Yanhuan

AU - Yin, Yiyi

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2026.

PY - 2026

Y1 - 2026

N2 - Grinding is a traditional yet critical process in manufacturing, and the integration of robotic systems can significantly enhance grinding performance while ensuring worker safety. However, current robotic grinding systems primarily rely on manual teaching or offline programming for trajectory generation. Moreover, these methods are often cumbersome and lack scalability. In this paper, a refined trajectory planning approach based on machine vision perception is introduced, aiming to address the issue of limited autonomy in traditional trajectory planning methods. Specifically, for full-surface grinding, a detection algorithm is developed to identify the polishing area on raised, welded and rough surface, enabling precise positioning of the target areas. Two toolpath patterns, a “bow” shape and a “Z” shape, are designed to cover the surface efficiently. For point-by-point polishing, an improved Laplacian matrix is introduced into the Laplacian-Based Contraction pipeline to improve the detection accuracy of key polishing points. The shortest path in the graph is then transferred to 3D space, where a point cloud eight-neighborhood graph is constructed. A minimum spanning tree algorithm is used to simplify the graph, facilitating trajectory sorting and endpoint positioning. The proposed trajectory planning algorithm offers high adaptability to process requirements, including adjustments to grinding head size, depth, angle, path density, and fitting accuracy. Finally, the effectiveness and accuracy of trajectory planning are verified by applying the proposed algorithm to the actual grinding robot.

AB - Grinding is a traditional yet critical process in manufacturing, and the integration of robotic systems can significantly enhance grinding performance while ensuring worker safety. However, current robotic grinding systems primarily rely on manual teaching or offline programming for trajectory generation. Moreover, these methods are often cumbersome and lack scalability. In this paper, a refined trajectory planning approach based on machine vision perception is introduced, aiming to address the issue of limited autonomy in traditional trajectory planning methods. Specifically, for full-surface grinding, a detection algorithm is developed to identify the polishing area on raised, welded and rough surface, enabling precise positioning of the target areas. Two toolpath patterns, a “bow” shape and a “Z” shape, are designed to cover the surface efficiently. For point-by-point polishing, an improved Laplacian matrix is introduced into the Laplacian-Based Contraction pipeline to improve the detection accuracy of key polishing points. The shortest path in the graph is then transferred to 3D space, where a point cloud eight-neighborhood graph is constructed. A minimum spanning tree algorithm is used to simplify the graph, facilitating trajectory sorting and endpoint positioning. The proposed trajectory planning algorithm offers high adaptability to process requirements, including adjustments to grinding head size, depth, angle, path density, and fitting accuracy. Finally, the effectiveness and accuracy of trajectory planning are verified by applying the proposed algorithm to the actual grinding robot.

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KW - grinding robot

KW - point-by-point polishing process

KW - trajectory planning

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Wang X, Ma H, Bian J, Jiang Y, Yin Y. Design and Application of Grinding Trajectory Planning Algorithm for Casting Grinding Robot. In Ma H, Xin B, She J, Yoshida S, editors, Advanced Computational Intelligence and Intelligent Informatics - 9th International Workshop, IWACIII 2025, Proceedings. Springer Science and Business Media Deutschland GmbH. 2026. p. 602-619. (Communications in Computer and Information Science). doi: 10.1007/978-981-95-6736-2_43