Attention-driven next-best-view planning for efficient reconstruction of plants and targeted plant parts

IF 4.4 1区 农林科学 Q1 AGRICULTURAL ENGINEERING Biosystems Engineering Pub Date : 2024-08-17 DOI:10.1016/j.biosystemseng.2024.08.002
Akshay K. Burusa, Eldert J. van Henten, Gert Kootstra
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Abstract

Robots in tomato greenhouses need to perceive the plant and plant parts accurately to automate monitoring, harvesting, and de-leafing tasks. Existing perception systems struggle with the high levels of occlusion in plants and often result in poor perception accuracy. One reason for this is because they use fixed cameras or predefined camera movements. Next-best-view (NBV) planning presents an alternate approach, in which the camera viewpoints are reasoned and strategically planned such that the perception accuracy is improved. However, existing NBV-planning algorithms are agnostic to the task-at-hand and give equal importance to all the plant parts. This strategy is inefficient for greenhouse tasks that require targeted perception of specific plant parts, such as the perception of leaf nodes for de-leafing. To improve targeted perception in complex greenhouse environments, NBV planning algorithms need an attention mechanism to focus on the task-relevant plant parts. In this paper, the role of attention in improving targeted perception using an attention-driven NBV planning strategy was investigated. Through simulation experiments using plants with high levels of occlusion and structural complexity, it was shown that focusing attention on task-relevant plant parts can significantly improve the speed and accuracy of 3D reconstruction. Further, with real-world experiments, it was shown that these benefits extend to complex greenhouse conditions with natural variation and occlusion, natural illumination, sensor noise, and uncertainty in camera poses. The results clearly indicate that using attention-driven NBV planning in greenhouses can significantly improve the efficiency of perception and enhance the performance of robotic systems in greenhouse crop production.

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注意力驱动下一最佳视角规划,高效重建植物和目标植物部位
番茄温室中的机器人需要准确感知植物和植物的各个部分,以便自动完成监控、收获和去叶任务。现有的感知系统难以应对植物的高遮挡度,往往导致感知精度低下。其中一个原因是这些系统使用固定的摄像头或预定义的摄像头移动。下一个最佳视角(NBV)规划提出了另一种方法,即对摄像机视点进行推理和战略规划,从而提高感知精度。然而,现有的 NBV 规划算法与手头的任务无关,对所有植物部分都同等重视。对于需要有针对性地感知特定植物部位的温室任务(如感知叶片节点以进行摘叶)来说,这种策略效率低下。为了提高复杂温室环境中的定向感知能力,NBV 规划算法需要一种注意力机制来关注与任务相关的植物部分。本文利用注意力驱动的 NBV 规划策略,研究了注意力在改善目标感知中的作用。通过使用具有高度遮挡和结构复杂性的植物进行模拟实验,结果表明,将注意力集中在与任务相关的植物部分可以显著提高三维重建的速度和准确性。此外,真实世界的实验还表明,这些优势可以扩展到具有自然变化和遮挡、自然光照、传感器噪声以及相机姿势不确定性的复杂温室条件。研究结果清楚地表明,在温室中使用注意力驱动的 NBV 规划可以显著提高感知效率,增强机器人系统在温室作物生产中的性能。
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来源期刊
Biosystems Engineering
Biosystems Engineering 农林科学-农业工程
CiteScore
10.60
自引率
7.80%
发文量
239
审稿时长
53 days
期刊介绍: Biosystems Engineering publishes research in engineering and the physical sciences that represent advances in understanding or modelling of the performance of biological systems for sustainable developments in land use and the environment, agriculture and amenity, bioproduction processes and the food chain. The subject matter of the journal reflects the wide range and interdisciplinary nature of research in engineering for biological systems.
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