Changes in the Hyperspectral Characteristics of Wheat Plants According to N Top-dressing Rates at Various Growth Stages

The Korean Journal of Crop Science Pub Date : 2020-12-01 DOI:10.7740/KJCS.2020.65.4.377

Jae Gyeong Jung, Y. Lee, J. Choi, G. Song, Jonghan Ko, Kyungdo Lee, S. Shim

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Abstract

Recently, wheat consumption has been increasing in Korea, requiring increased production. Nitrogen fertilization is a critical determinant in crop yield; therefore, it is necessary to optimize the nitrogen fertilization regime with current trends that emphasize the minimum impact of nitrogen fertilizer on the environment. In this study, both nondestructive spectral analysis using a hyperspectral camera and growth analysis were performed to determine the optimal N top-dressing rates after heading. The nitrogen application regimes consisted of three conditions according to the secondary top-dressing rate: N4:3:0 (0 kg 10 a ), N4:3:3 (2.73 kg 10 a-1), and N4:3:6 (5.46 kg 10 a -1). Subsequently, growth and physiological investigations were performed at the jointing, heading, and ripening stages of wheat, and spectral investigations were conducted. On April 29, as the nitrogen fertilization rate was increased to N4:3:3 and N4:3:6, plant height and grain yield increased by 4% and 8%, and 8% and 52%, respectively, compared to those under N4:3:0. Leaf area index and SPAD value also increased by 13% and 24%, and 32% and 43%, respectively. The R (red), G (green), and B (blue) of leaf color were lowered by 15, 11, and 4 in N4:3:3 and 44, 34, and 18 in N4:3:6, respectively, as compared to the control. Grain yield was the highest at high top-dressing (N4:3:6), however, there was no difference between no top-dressing (N4:3:0) and intermediat top-dressing (N4:3:3). The reflectance analyzed using a hyperspectral camera showed a difference in the near-infrared (NIR) region on March 19, and on April 29, there was a difference both in the visible light region greater than 550 nm and the NIR region. Vegetation indices differed according to fertilization regime, except for the greenness index (GI). The results of this study showed that not only growth and physiological analysis but also spectral indices can be used to optimize the nitrogen top-dressing rate.

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不同生育期氮素追肥量对小麦植株高光谱特性的影响

最近，国内小麦消费量不断增加，因此需要增加产量。氮肥是作物产量的关键决定因素;因此，有必要根据当前的趋势优化氮肥施用制度，以强调氮肥对环境的影响最小。在本研究中，利用高光谱相机进行非破坏性光谱分析和生长分析，以确定抽穗后的最佳氮肥追肥率。根据二次追肥速率，施氮量为N4:3:0 (0 kg - 10 a)、N4:3:3 (2.73 kg - 10 a-1)和N4:3:6 (5.46 kg - 10 a-1)。随后，在小麦拔节、抽穗和成熟阶段进行生长和生理研究，并进行光谱研究。4月29日，当施氮量增加到N4:3:3和N4:3:6时，株高和籽粒产量分别比N4:3:0时提高了4%和8%，提高了8%和52%。叶面积指数和SPAD值分别提高了13%和24%，32%和43%。与对照相比，N4:3:3处理叶片颜色R(红色)、G(绿色)和B(蓝色)分别降低了15、11和4,N4:3:6处理叶片颜色R(红色)、G(绿色)和B(蓝色)分别降低了44、34和18。籽粒产量以高追肥(N4:3:6)最高，不追肥(N4:3:0)与中追肥(N4:3:3)无显著差异。利用高光谱相机分析的反射率显示，3月19日在近红外(NIR)区域存在差异，4月29日在大于550 nm的可见光区域和近红外区域都存在差异。除绿度指数(GI)外，不同施肥方式的植被指数存在差异。本研究结果表明，不仅可以通过生长和生理分析，还可以通过光谱指标来优化氮肥追肥速率。

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The Korean Journal of Crop Science

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