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矮化、高密度藏红花双臂采摘序列的高效协同规划方法研究

Investigation into the Efficient Cooperative Planning Approach for Dual-Arm Picking Sequences of Dwarf, High-Density Safflowers.

作者信息

Zhang Zhenguo, Xu Peng, Xie Binbin, Wang Yunze, Shi Ruimeng, Li Junye, Cao Wenjie, Chu Wenqiang, Zeng Chao

机构信息

College of Mechanical and Electrical Engineering, Xinjiang Agricultural University, Urumqi 830052, China.

Key Laboratory of Xinjiang Intelligent Agricultural Equipment, Xinjiang Agricultural University, Urumqi 830052, China.

出版信息

Sensors (Basel). 2025 Jul 17;25(14):4459. doi: 10.3390/s25144459.

DOI:10.3390/s25144459
PMID:40732587
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12298643/
Abstract

Path planning for picking safflowers is a key component in ensuring the efficient operation of robotic safflower-picking systems. However, existing single-arm picking devices have become a bottleneck due to their limited operating range, and a breakthrough in multi-arm cooperative picking is urgently needed. To address the issue of inadequate adaptability in current path planning strategies for dual-arm systems, this paper proposes a novel path planning method for dual-arm picking (LTSACO). The technique centers on a dynamic-weight heuristic strategy and achieves optimization through the following steps: first, the K-means clustering algorithm divides the target area; second, the heuristic mechanism of the Ant Colony Optimization (ACO) algorithm is improved by dynamically adjusting the weight factor of the state transition probability, thereby enhancing the diversity of path selection; third, a 2-OPT local search strategy eliminates path crossings through neighborhood search; finally, a cubic Bézier curve heuristically smooths and optimizes the picking trajectory, ensuring the continuity of the trajectory's curvature. Experimental results show that the length of the parallelogram trajectory, after smoothing with the Bézier curve, is reduced by 20.52% compared to the gantry trajectory. In terms of average picking time, the LTSACO algorithm reduces the time by 2.00%, 2.60%, and 5.60% compared to DCACO, IACO, and the traditional ACO algorithm, respectively. In conclusion, the LTSACO algorithm demonstrates high efficiency and strong robustness, providing an effective optimization solution for multi-arm cooperative picking and significantly contributing to the advancement of multi-arm robotic picking systems.

摘要

采摘红花的路径规划是确保机器人红花采摘系统高效运行的关键组成部分。然而,现有的单臂采摘设备由于其操作范围有限已成为瓶颈,迫切需要在多臂协同采摘方面取得突破。为了解决当前双臂系统路径规划策略中适应性不足的问题,本文提出了一种新颖的双臂采摘路径规划方法(LTSACO)。该技术以动态权重启发式策略为核心,并通过以下步骤实现优化:首先,使用K均值聚类算法划分目标区域;其次,通过动态调整状态转移概率的权重因子改进蚁群优化(ACO)算法的启发式机制,从而增强路径选择的多样性;第三,采用2-OPT局部搜索策略通过邻域搜索消除路径交叉;最后,使用三次贝塞尔曲线启发式地平滑和优化采摘轨迹,确保轨迹曲率的连续性。实验结果表明,与龙门轨迹相比,使用贝塞尔曲线平滑后的平行四边形轨迹长度减少了20.52%。在平均采摘时间方面,LTSACO算法与DCACO、IACO和传统ACO算法相比,分别将时间减少了2.00%、2.60%和5.60%。总之,LTSACO算法具有高效性和强鲁棒性,为多臂协同采摘提供了有效的优化解决方案,对多臂机器人采摘系统的发展做出了重要贡献。

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2
SDC-DeepLabv3+: Lightweight and Precise Localization Algorithm for Safflower-Harvesting Robots.SDC-DeepLabv3+:用于红花采摘机器人的轻量级精确定位算法
Plant Phenomics. 2024 Jul 5;6:0194. doi: 10.34133/plantphenomics.0194. eCollection 2024.
3
Research on the local path planning of an orchard mowing robot based on an elliptic repulsion scope boundary constraint potential field method.
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Front Plant Sci. 2023 Jul 21;14:1184352. doi: 10.3389/fpls.2023.1184352. eCollection 2023.
4
Research on smooth path planning method based on improved ant colony algorithm optimized by Floyd algorithm.基于Floyd算法优化的改进蚁群算法的平滑路径规划方法研究
Front Neurorobot. 2022 Aug 24;16:955179. doi: 10.3389/fnbot.2022.955179. eCollection 2022.