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基于无人机高光谱遥感与WOFOST耦合的水稻分蘖期施肥决策方法研究

Research on fertilization decision method for rice tillering stage based on the coupling of UAV hyperspectral remote sensing and WOFOST.

作者信息

Li Shilong, Jin Zhongyu, Bai Juchi, Xiang Shuang, Xu Chenyi, Yu Fenghua

机构信息

College of Information and Electrical Engineering, Shenyang Agricultural University, Shenyang, China.

National Digital Agriculture Sub-center of Innovation (Northeast Region), Shenyang, China.

出版信息

Front Plant Sci. 2024 Jun 7;15:1405239. doi: 10.3389/fpls.2024.1405239. eCollection 2024.

DOI:10.3389/fpls.2024.1405239
PMID:38911973
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11190322/
Abstract

INTRODUCTION

The use of chemical fertilizers in rice field management directly affects rice yield. Traditional rice cultivation often relies on the experience of farmers to develop fertilization plans, which cannot be adjusted according to the fertilizer requirements of rice. At present, agricultural drones are widely used for early monitoring of rice, but due to their lack of rationality, they cannot directly guide fertilization. How to accurately apply nitrogen fertilizer during the tillering stage to stabilize rice yield is an urgent problem to be solved in the current large-scale rice production process.

METHODS

WOFOST is a highly mechanistic crop growth model that can effectively simulate the effects of fertilization on rice growth and development. However, due to its lack of spatial heterogeneity, its ability to simulate crop growth at the field level is weak. This study is based on UAV remote sensing to obtain hyperspectral data of rice canopy and assimilation with the WOFOST crop growth model, to study the decision-making method of nitrogen fertilizer application during the rice tillering stage. Extracting hyperspectral features of rice canopy using Continuous Projection Algorithm and constructing a hyperspectral inversion model for rice biomass based on Extreme Learning Machine. By using two data assimilation methods, Ensemble Kalman Filter and Four-Dimensional Variational, the inverted biomass of the rice biomass hyperspectral inversion model and the localized WOFOST crop growth model were assimilated, and the simulation results of the WOFOST model were corrected. With the average yield as the goal, use the WOFOST model to formulate fertilization decisions and create a fertilization prescription map to achieve precise fertilization during the tillering stage of rice.

RESULTS

The research results indicate that the training set and RMSE of the rice biomass hyperspectral inversion model are 0.953 and 0.076, respectively, while the testing set and RMSE are 0.914 and 0.110, respectively. When obtaining the same yield, the fertilization strategy based on the ENKF assimilation method applied less fertilizer, reducing 5.9% compared to the standard fertilization scheme.

DISCUSSION

This study enhances the rationality of unmanned aerial vehicle remote sensing machines through data assimilation, providing a new theoretical basis for the decision-making of rice fertilization.

摘要

引言

稻田管理中化肥的使用直接影响水稻产量。传统水稻种植往往依靠农民经验制定施肥计划,无法根据水稻需肥情况进行调整。目前,农业无人机广泛用于水稻早期监测,但由于缺乏合理性,无法直接指导施肥。在当前大规模水稻生产过程中,如何在分蘖期精准施用氮肥以稳定水稻产量是亟待解决的问题。

方法

WOFOST是一个高度机理化的作物生长模型,能有效模拟施肥对水稻生长发育的影响。然而,由于缺乏空间异质性,其在田间尺度模拟作物生长的能力较弱。本研究基于无人机遥感获取水稻冠层高光谱数据,并与WOFOST作物生长模型同化,研究水稻分蘖期氮肥施用决策方法。利用连续投影算法提取水稻冠层高光谱特征,构建基于极限学习机的水稻生物量高光谱反演模型。采用集合卡尔曼滤波和四维变分两种数据同化方法,对水稻生物量高光谱反演模型反演的生物量与本地化的WOFOST作物生长模型进行同化,校正WOFOST模型的模拟结果。以平均产量为目标,利用WOFOST模型制定施肥决策并生成施肥处方图,实现水稻分蘖期精准施肥。

结果

研究结果表明,水稻生物量高光谱反演模型的训练集 和均方根误差分别为0.953和0.076,测试集 和均方根误差分别为0.914和0.110。在获得相同产量时,基于集合卡尔曼滤波同化方法的施肥策略施肥量较少,比标准施肥方案减少5.9%。

讨论

本研究通过数据同化提高了无人机遥感的合理性,为水稻施肥决策提供了新的理论依据。

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