Assessment of Leaf Area and Biomass through AI-Enabled Deployment

Dmitrii G. Shadrin, A. Menshchikov, Artem V. Nikitin, G. Ovchinnikov, Vera Volohina, S. Nesteruk, M. Pukalchik, M. Fedorov, A. Somov
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Abstract

Leaf area and biomass are important morphological parameters for in situ plant monitoring since a leaf is vital for perceiving and capturing the environmental light as well as represents the overall plant development. The traditional approach for leaf area and biomass measurements is destructive requiring manual labor and may cause damages for the plants. In this work, we report on the AI-based approach for assessing and predicting the leaf area and plant biomass. The proposed approach is able to estimate and predict the overall plants biomass at the early stage of growth in a non-destructive way. For this reason we equip an industrial greenhouse for cucumbers growing with the commercial off-the-shelf environmental sensors and video cameras. The data from sensors are used to monitor the environmental conditions in the greenhouse while the top-down images are used for training Fully Convolutional Neural Networks (FCNN). The FCNN performs the segmentation task for leaf area calculation resulting in 82% accuracy. Application of trained FCNNs to the sequences of camera images allowed the reconstruction of per-plant leaf area and their growth-dynamics. Then we established the dependency between the average leaf area and biomass using the direct measurements of the biomass. This in turn allowed for reconstruction and prediction of the dynamics of biomass growth in the greenhouse using the image data with 10% average relative error for the 12 days prediction horizon. The actual deployment showed the high potential of the proposed data-driven approaches for plant growth dynamics assessment and prediction. Moreover, it closes the gap towards constructing fully closed autonomous greenhouses for harvests and plants biological safety.
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通过人工智能部署评估叶面积和生物量
叶片面积和生物量是植物原位监测的重要形态学参数,因为叶片对感知和捕捉环境光至关重要,也代表了植物的整体发育。传统的测量叶面积和生物量的方法是破坏性的,需要人工劳动,并且可能对植物造成损害。在这项工作中,我们报告了基于人工智能的评估和预测叶面积和植物生物量的方法。该方法能够以非破坏性的方式估计和预测植物生长早期的总体生物量。出于这个原因,我们为黄瓜种植配备了一个工业温室,配备了商业上现成的环境传感器和摄像机。来自传感器的数据用于监测温室的环境条件,而自上而下的图像用于训练全卷积神经网络(FCNN)。FCNN对叶面积计算执行分割任务,准确率达到82%。将训练好的fcnn应用于相机图像序列,可以重建单株叶面积及其生长动态。然后利用生物量的直接测量,建立了平均叶面积与生物量之间的依赖关系。这反过来又允许利用12天预测范围内平均相对误差为10%的图像数据重建和预测温室内生物量增长的动态。实际部署表明,数据驱动方法在植物生长动态评估和预测方面具有很大的潜力。此外,它还缩小了为收获和植物生物安全建设全封闭自主温室的差距。
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