An Integrated Route and Path Planning Strategy for Skid–Steer Mobile Robots in Assisted Harvesting Tasks with Terrain Traversability Constraints

Q2 Agricultural and Biological Sciences

Agriculture Pub Date : 2024-07-23 DOI:10.3390/agriculture14081206

R. Urvina, César Leonardo Guevara, J. P. Vásconez, A. Prado

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引用次数: 0

Abstract

This article presents a combined route and path planning strategy to guide Skid–Steer Mobile Robots (SSMRs) in scheduled harvest tasks within expansive crop rows with complex terrain conditions. The proposed strategy integrates: (i) a global planning algorithm based on the Traveling Salesman Problem under the Capacitated Vehicle Routing approach and Optimization Routing (OR-tools from Google) to prioritize harvesting positions by minimum path length, unexplored harvest points, and vehicle payload capacity; and (ii) a local planning strategy using Informed Rapidly-exploring Random Tree (IRRT*) to coordinate scheduled harvesting points while avoiding low-traction terrain obstacles. The global approach generates an ordered queue of harvesting locations, maximizing the crop yield in a workspace map. In the second stage, the IRRT* planner avoids potential obstacles, including farm layout and slippery terrain. The path planning scheme incorporates a traversability model and a motion model of SSMRs to meet kinematic constraints. Experimental results in a generic fruit orchard demonstrate the effectiveness of the proposed strategy. In particular, the IRRT* algorithm outperformed RRT and RRT* with 96.1% and 97.6% smoother paths, respectively. The IRRT* also showed improved navigation efficiency, avoiding obstacles and slippage zones, making it suitable for precision agriculture.

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滑移式移动机器人在地形可穿越性约束条件下执行辅助收割任务时的综合路线和路径规划策略

本文提出了一种路线和路径规划相结合的策略，用于引导滑移式移动机器人（SSMRs）在复杂地形条件下的广阔作物行内按计划完成收割任务。所提出的策略整合了：(i) 基于有容量车辆路由方法下的旅行推销员问题和优化路由（谷歌提供的 OR 工具）的全局规划算法，根据最小路径长度、未开发的收割点和车辆有效载荷容量确定收割位置的优先顺序；(ii) 使用知情快速探索随机树（IRRT*）的局部规划策略，在避开低牵引力地形障碍物的同时协调预定的收割点。全局方法生成有序的收割地点队列，最大限度地提高工作区地图上的作物产量。在第二阶段，IRRT*规划器会避开潜在的障碍物，包括农场布局和湿滑地形。路径规划方案结合了 SSMR 的可穿越性模型和运动模型，以满足运动学约束条件。在一个普通果园中的实验结果证明了所提策略的有效性。其中，IRRT*算法的平滑路径率分别为96.1%和97.6%，优于RRT和RRT*算法。IRRT* 算法还提高了导航效率，避开了障碍物和打滑区域，适用于精准农业。

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来源期刊

Agriculture Agricultural and Biological Sciences-Horticulture

CiteScore

1.90

自引率

0.00%

发文量

审稿时长

11 weeks

期刊介绍： The Agriculture (Poľnohospodárstvo) is a peer-reviewed international journal that publishes mainly original research papers. The journal examines various aspects of research and is devoted to the publication of papers dealing with the following subjects: plant nutrition, protection, breeding, genetics and biotechnology, quality of plant products, grassland, mountain agriculture and environment, soil science and conservation, mechanization and economics of plant production and other spheres of plant science. Journal is published 4 times per year.