具有冠层结构特征的玉米作物叶绿素估测增强模型:使用多光谱无人机图像和机器学习算法

IF 5.8 2区 环境科学与生态学 Q1 ECOLOGY
Gaurav Singhal , Burhan U. Choudhury , Naseeb Singh , Jonali Goswami
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引用次数: 0

摘要

叶片叶绿素浓度(LCC)是叶片含氮量(N)的关键指标,冠层结构的变化,尤其是叶面积指数(LAI),在估算叶绿素浓度方面发挥着重要作用。叶绿素光谱预测模型是及时进行营养管理的有用工具,特别是在精准农业中。然而,叶绿素总量估算的准确性受到 LAI 的影响。将 LAI 数据作为光谱预测模型的输入仍不足以改善 LCC 估算。本研究利用无人飞行器(UAV)拍摄的高分辨率(5 厘米)多光谱图像,测试了将 LAI 作为输入可提高 LCC 估计精度的假设。为此,在梅加拉亚邦的丘陵生态系统中,以玉米为试验作物,在不同的养分管理条件下进行了种植。在无人飞行器飞行的同时,采用实验室破坏法对地面取样进行 LCC 测量。采用随机森林(RF)、支持向量机(SVM)和核岭回归(KKR)等机器学习算法,利用波段反射率、植被指数和测量的叶绿素建立了 LCC 估算模型。利用 LAI 数据评估了该模型对 LCC 估算的灵敏度。KKR 在估计 LCC 的准确性方面比其他两种算法(RF 和 SVM)高出 11.0% 到 19.0%。加入 LAI 后,KKR 衍生的 LCC 估算模型得到了明显改善(R2 从 0.785 提高到 0.928,RMSE 从 0.065 降低到 0.053 mg g-1)。该模型的可靠性已在多次无人机飞行中得到证实,飞行对象为健康和营养不良的玉米作物。因此,利用 KKR 算法从多光谱无人机图像中推导出的 LCC 模型可有助于在山区生态系统中采用田间规模的精准农业。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
An enhanced chlorophyll estimation model with a canopy structural trait in maize crops: Use of multi-spectral UAV images and machine learning algorithm

Leaf chlorophyll concentration (LCC) is a key indicator of leaf nitrogen (N) and changes in canopy structure, particularly the leaf area index (LAI), play a significant role in estimating LCC. Spectral prediction models for chlorophyll are a useful tool for timely nutritional management, particularly in precision agriculture. However, the accuracy of LCC estimation is influenced by the LAI. Considering LAI data as input in the spectral prediction model is still inadequate for improving LCC estimation. This study tested the hypothesis that LCC estimate accuracy could be enhanced by using LAI as an input using high-resolution (5 cm) multi-spectral images from an unmanned aerial vehicle (UAV). For this, maize was grown as a test crop under different nutrient management in the hilly ecosystem of Meghalaya. LCC was measured using laboratory destruction methods from ground sampling that coincided with UAV flights. Machine learning algorithms such as random forest (RF), support vector machine (SVM), and kernel ridge regression (KKR) were employed to develop the LCC estimation model, utilizing band reflectance, vegetation indexes, and measured chlorophyll. The model was assessed for its sensitivity to LCC estimation using LAI data. KKR outperformed other two algorithms (RF and SVM) in accuracy of LCC estimation by >11.0 to 19.0 %. The KKR-derived LCC estimation model was significantly improved by the inclusion of LAI (R2 increased from 0.785 to 0.928 and RMSE decreased from 0.065 to 0.053 mg g−1). The model's reliability was proven on multiple UAV flights for maize crops that are healthy and nutrient-stressed. Thus, LCC models derived from multispectral UAV images using KKR algorithms could benefit the adoption of precision agriculture at field scale in mountain ecosystems.

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来源期刊
Ecological Informatics
Ecological Informatics 环境科学-生态学
CiteScore
8.30
自引率
11.80%
发文量
346
审稿时长
46 days
期刊介绍: The journal Ecological Informatics is devoted to the publication of high quality, peer-reviewed articles on all aspects of computational ecology, data science and biogeography. The scope of the journal takes into account the data-intensive nature of ecology, the growing capacity of information technology to access, harness and leverage complex data as well as the critical need for informing sustainable management in view of global environmental and climate change. The nature of the journal is interdisciplinary at the crossover between ecology and informatics. It focuses on novel concepts and techniques for image- and genome-based monitoring and interpretation, sensor- and multimedia-based data acquisition, internet-based data archiving and sharing, data assimilation, modelling and prediction of ecological data.
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