An efficient headland-turning navigation system for a safflower picking robot

IF 2.4 4区 农林科学 Q2 AGRICULTURAL ENGINEERING Journal of Agricultural Engineering Pub Date : 2023-10-11 DOI:10.4081/jae.2023.1539
Guomin Gao, Hui Guo, Jing Zhang, Zhenguo Zhang, Tianlun Wu, Hao Lu, Zhaoxin Qiu, Haiyang Chen, Zhen Lingxuan
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Abstract

This study proposes a navigation system for the headland autonomous turning of a safflower picking robot. The proposed system includes binocular cameras, differential satellites, and inertial sensors. The method of extracting the headland boundary line combining the hue, saturation, and value-fixed threshold segmentation method and random sample consensus algorithm and planning the headland-turning trajectory of a robot based on the multiorder Bezier curve are used as control methods. In addition, a headland-turning tracking model of a safflower picking robot is designed, and a path-tracking control algorithm is developed. A field test verifies the performance of the designed headland-turning navigation system. The test results show that the accuracy of the judgment result regarding the existence of a headland is higher than 96%. In headland boundary detection, the angle deviation is less than 1.5˚, and the depth value error is less than 50 mm. The headland-turning path tracking test result shows that at a turning speed of 0.5 km/h, the average lateral deviation is 37 mm, and the turning time is 24.2 seconds. Compared to the 1 km/h, the turning speed of 0.5 km/h provides a better trajectory tracking effect, but the turning time is longer. The test results verify that this navigation system can accurately extract the headland boundary line and can successfully realise the headland-turning path tracking of a safflower picking robot. The results presented in this study can provide a useful reference for the autonomous navigation of a field robot.
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一种用于红花采摘机器人的高效转弯导航系统
本研究提出一种红花采摘机器人的海岬自主转弯导航系统。该系统包括双目摄像机、差分卫星和惯性传感器。采用了结合色相、饱和度、定值阈值分割法和随机样本一致性算法的岬角边界线提取方法和基于多阶贝塞尔曲线的机器人转弯轨迹规划方法作为控制方法。此外,设计了红花采摘机器人的掉头跟踪模型,并开发了路径跟踪控制算法。现场试验验证了所设计的转海导航系统的性能。试验结果表明,该方法对海岬是否存在的判断准确率可达96%以上。在岬角边界检测中,角度偏差小于1.5˚,深度值误差小于50 mm。转弯路径跟踪试验结果表明,在转弯速度为0.5 km/h时,平均横向偏差为37 mm,转弯时间为24.2 s。与1 km/h相比,0.5 km/h的转弯速度提供了更好的轨迹跟踪效果,但转弯时间更长。实验结果表明,该导航系统能够准确地提取岬角边界线,成功地实现了红花采摘机器人的岬角转弯路径跟踪。研究结果可为野外机器人的自主导航提供有益的参考。
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来源期刊
Journal of Agricultural Engineering
Journal of Agricultural Engineering AGRICULTURAL ENGINEERING-
CiteScore
2.30
自引率
5.60%
发文量
40
审稿时长
10 weeks
期刊介绍: The Journal of Agricultural Engineering (JAE) is the official journal of the Italian Society of Agricultural Engineering supported by University of Bologna, Italy. The subject matter covers a complete and interdisciplinary range of research in engineering for agriculture and biosystems.
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