Original Articles
Early Access
https://doi.org/10.4081/jae.2026.2024

A safety-refined and smoothness-enhanced path-planning algorithm for an agricultural composite mobile manipulator in greenhouse crate handling

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Published: 5 June 2026
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Artificial potential field, automated greenhouse logistics, composite mobile manipulator, industrial automation, path planning, RRT algorithm

Authors

Haoxuan Hu
School of Mechanical and Automotive Engineering, Shanghai University of Engineering Science, Shanghai, China.
Chunyan Zhang
cyzhang@sues.edu.cn
School of Mechanical and Automotive Engineering, Shanghai University of Engineering Science, Shanghai, China.

With the growing demand for automation in greenhouse logistics, ensuring both operational safety and motion smoothness has become a key challenge for composite mobile manipulators working in confined agricultural environments. This study proposes a safety-refined and smoothness-enhanced path-planning algorithm, termed SR-RRT-APF, to improve path feasibility and collision avoidance for agricultural robotic systems. The method integrates scheduled goal biasing, curvature-aware parent-node selection, density-adaptive step sizing, and potential-field-based soft guidance into an improved RRT framework. By incorporating explicit minimum-clearance constraints and lightweight post-processing, the algorithm jointly optimizes safety margins and geometric smoothness during the path generation stage. Extensive simulations and prototype-level tests were conducted on a greenhouse crate-handling robot equipped with a 6-DOF manipulator and a vision-guided mobile chassis. Ten consecutive crate-handling cycles were performed, in which the robot autonomously recognized, grasped, transported, and placed vegetable crates within narrow greenhouse aisles. Results from the simulation benchmarks show that SR-RRT-APF achieves superior path quality, larger safety margins, and improved smoothness compared with the benchmark algorithms in dense and constrained workspaces. Prototype-level experiments on a greenhouse crate-handling robot further support the system-level feasibility of the associated perception–manipulation workflow, indicating the practical relevance of the proposed method in greenhouse operations while also suggesting its applicability to a broader class of constrained-space planning problems.

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CRediT authorship contribution

Haoxuan Hu, conceptualization, software (SR-RRT-APF algorithm), writing – original draft. Chunyan Zhang, supervision, formal analysis, writing – review & editing. All authors read and approved the final version of the manuscript.

Data Availability Statement

All data generated or analyzed during this study are available from the corresponding author upon reasonable request.

How to Cite



“A safety-refined and smoothness-enhanced path-planning algorithm for an agricultural composite mobile manipulator in greenhouse crate handling” (2026) Journal of Agricultural Engineering [Preprint]. doi:10.4081/jae.2026.2024.
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