Modification of an automated precision farming robot for high temporal resolution measurement of leaf angle dynamics using stereo vision

IF 1.6 Q2 MULTIDISCIPLINARY SCIENCES

MethodsX Pub Date : 2025-01-13 DOI:10.1016/j.mex.2025.103169

Frederik Hennecke , Jonas Bömer , René H.J. Heim

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引用次数: 0

Abstract

In agriculture, the plant leaf angle influences light use efficiency and photosynthesis and, consequently, the overall crop performance. Leaf angle measurements are used in plant phenotyping, plant breeding, and remote sensing to study plant function and structure. Traditional manual leaf angle measurements have limited precision as they are labor- and time-intensive due to challenging environmental conditions and highly dynamic plant processes. To enable more detailed studies on leaf angles, we modified a well-established automated farming robot to obtain high-resolution 3D point clouds at customizable intervals of individual plants using stereo vision. We demonstrate the system's accuracy and reliability, with minimal deviation from reference values. The method can be utilized by other researchers to gather data on leaf angles and other structural plant traits at regular intervals to access the dynamics of leaves, plants, and canopies. The system's low cost and adaptability can enhance the efficiency of crop monitoring in plant breeding and phenotyping experiments. Detailed documentation and code are available on GitHub.

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An open-source farming robot is retrofitted to function as an automatic data collection platform
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Hard to access leaf angles can be retrieved with high accuracy
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Leaf angle dynamics can be observed with high temporal resolution

Abstract Image