模拟LED生长室内大豆冠层内的光谱

T. Hitz, M. Henke, S. Graeff‐Hönninger, Sebastian Munz
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引用次数: 3

摘要

了解光谱对不同作物的影响对于探索利用LED照明调节作物生长和质量的可能性非常重要。功能结构植物模型可以成为处理大量实验处理所需的重要工具,以确定特定波长的影响以及与其他环境因素的相互作用。因此,目标是创建一个虚拟环境,可以模拟在LED生长室内生长的大豆冠层内的光强度和光谱。测量在两个日期,两个植物组和两个位置进行。模拟光强准确,R2在0.798 ~ 0.956之间;平均绝对百分比误差在5.85 ~ 35.14%之间,模拟的冠层下光谱变化与测量值相似。GroIMP中选择的GPUFlux模型可用于对光谱和强度的响应进行功能性结构植物建模,并探索LED腔室内的最佳实验设计。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Simulating light spectrum within a soybean canopy in an LED growth chamber
Knowledge on the effect of light spectra on different crops is important in the exploration of possibilities to regulate crop growth and quality with LED lighting. Functional structural plant modelling can be an important tool to cope with the large number of experimental treatments necessary to identify the effect of specific wavelengths and the interaction with other environmental factors. Therefore, the objectives were to create a virtual environment that can simulate light intensity and spectrum within a soybean canopy grown within an LED growth chamber. Measurements were made at two dates, on two plant sets and at two placements. Simulated light intensities were accurate with a R2 between 0.798 and 0.956; mean absolute percentage errors between 5.85 and 35.14 % and simulated change in light spectrum below the canopy changed similar to the measurements. The chosen GPUFlux model in GroIMP can be used for functional structural plant modelling in response to light spectra and intensity and to explore an optimal experimental design within an LED chamber.
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