Developing models to detect maize diseases using spectral vegetation indices derived from spectral signatures

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Basani Lammy Nkuna , Johannes George Chirima , Solomon W. Newete , Adolph Nyamugama , Adriaan Johannes van der Walt
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Abstract

Maize, a vital global crop, faces numerous challenges, including outbreaks. This study explores the use of spectral vegetation indices for the early detection of maize diseases in individual leaves based on crop phenology at the vegetative, tasselling, and maturity stages. The research was conducted in rural areas of Giyani in the Limpopo province, South Africa, where smallholder farmers heavily rely on maize production for sustenance. Fungal and viral diseases pose significant threats to maize crops, necessitating precise and timely disease detection methods. Hyperspectral remote sensing, with its ability to capture detailed spectral information, offers a promising solution. The study analysed spectral reflectance data collected from healthy and diseased maize leaves. Various vegetation indices derived from spectral signatures, including the Normalized difference vegetation index (NDVI), Anthocyanin Reflectance Index (ARI), photochemical Reflectance Index (PRI), and Carotenoid Reflectance Index (CRI) were investigated for their ability to show disease-related spectral variations. The results indicated that during the tasselling stage, the spectral differences had minimum absorption in the blue region. However, a distinct shift in spectral reflectance was observed during the vegetative stage with 70 % increase in reflectance. First derivative reflectance analysis revealed peaks at approximately 715 nm and 722 nm, which were useful in the discrimination of the different growth stages. Generalized Linear Models (GLM) with binomial link functions and Akaike Information Criterion (AIC) showed that individual vegetation indices performed equally well. NDVI (P<0.001) and CRI (P<0.000) showed the lowest AIC values across all growth stages, suggesting their potential as effective disease indicators. These findings underscores the significance of employing remote sensing technology and spectral analysis as essential tools in the endeavours to tackle the difficulties encountered by maize growers, especially those operating small-scale farms, and to advance sustainable farming practices and ensure food security.

利用光谱特征得出的光谱植被指数开发检测玉米病害的模型
玉米作为一种重要的全球作物,面临着包括病害爆发在内的诸多挑战。本研究探讨了如何利用光谱植被指数,根据作物的生长期、抽穗期和成熟期的物候,及早发现玉米单叶的病害。研究在南非林波波省吉亚尼的农村地区进行,那里的小农严重依赖玉米生产维持生计。真菌和病毒性疾病对玉米作物构成重大威胁,因此需要精确、及时的疾病检测方法。高光谱遥感技术能够捕捉到详细的光谱信息,是一种很有前景的解决方案。这项研究分析了从健康和患病玉米叶片上收集到的光谱反射率数据。研究了从光谱特征得出的各种植被指数,包括归一化差异植被指数 (NDVI)、花青素反射率指数 (ARI)、光化学反射率指数 (PRI) 和类胡萝卜素反射率指数 (CRI),看它们是否能显示与疾病相关的光谱变化。结果表明,在抽穗期,光谱差异在蓝色区域的吸收最小。然而,在植株生长阶段,光谱反射率出现了明显的变化,反射率增加了 70%。一阶导数反射率分析显示了约 715 纳米和 722 纳米的峰值,这些峰值有助于区分不同的生长阶段。具有二叉连接功能的广义线性模型(GLM)和阿凯克信息标准(AIC)表明,各个植被指数的表现同样出色。在所有生长阶段中,NDVI(P<0.001)和 CRI(P<0.000)的 AIC 值最低,表明它们有可能成为有效的疾病指标。这些研究结果突出表明,遥感技术和光谱分析是解决玉米种植者,尤其是小规模农场经营者所遇到的困难、推进可持续农业实践和确保粮食安全的重要工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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