Computational neural network for processing light-reflective spectra of plants and remote phytosanitary monitoring of potatoes

N. Vorobyov, A. Lysov, T. Kornilov, A. V. Hyutti
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Abstract

The article is devoted to studying the possibility of using the WaveLetNN artificial neural network to analyze the results of remote phytosanitary monitoring of early detection of plants in potato plantings affected by late blight. Various methods for analyzing the spectral characteristics of plant reflection are considered, including the classification method. To detect plants infected with late blight, the WaveLetNN neural network analyzes the light reflective characteristics of potato plants obtained as a result of research (in the range of 300–1100 nm) and calculates the cognitive significance index (CSI = 0...10), which characterizes the intensity of biochemical processes inside plants aimed at countering phytopathogenic microflora. It was found that a significant increase in the CSI index signals infection of plants by phytopathogenic microflora and activation of protective biochemical processes on the part of plants. To reliably indicate infected plants, the WaveLetNN neural network underwent test training on a large number of light reflectance spectra of uninfected plants and plants artificially infected with late blight. The spectral reflectance characteristics of infected and uninfected plants were measured during 3, 4, 7 and 8 days after infection. Processing the obtained spectra using the WaveLetNN neural network made it possible to identify significant differences between the second- and third-order spectral characteristics of uninfected and late blight infected plants on the third day after infection. Moreover, for infected plants the CSI index values were 6.1...6.7, and CSI for healthy plants – 1.9...2.5. The Wave-LetNN neural network eliminates the influence on the light reflectance spectra of the spatial arrangement of plant leaves, unevenness of the soil surface and shading of individual sections of the field, normalizing the spectra to the total intensity of light reflected from the leaves. Thus, the WaveLetNN neural network can be used as the software core of online systems for remote phytosanitary monitoring of potato plants.
处理植物光反射光谱和马铃薯远程植物检疫监测的计算神经网络
文章致力于研究使用 WaveLetNN 人工神经网络分析远程植物检疫监测结果的可能性,以早期发现受晚疫病影响的马铃薯种植园中的植物。考虑了各种分析植物反射光谱特征的方法,包括分类方法。为了检测感染晚疫病的植株,WaveLetNN 神经网络分析了作为研究成果获得的马铃薯植株的光反射特征(范围为 300-1100 纳米),并计算了认知意义指数(CSI = 0...10),该指数描述了植株内部旨在对抗植物病原微生物的生化过程的强度。研究发现,CSI 指数的显著增加预示着植物受到了植物病原微生物的感染,并启动了植物的保护性生化过程。为了可靠地指示受感染的植物,WaveLetNN 神经网络对大量未感染植物和人工感染晚疫病植物的光反射光谱进行了测试训练。感染和未感染植物的光谱反射特性是在感染后的 3、4、7 和 8 天内测量的。利用 WaveLetNN 神经网络处理所获得的光谱,可以确定未感染植物和感染晚疫病植物在感染后第三天的二阶和三阶光谱特征之间的显著差异。此外,受感染植物的 CSI 指数值为 6.1...6.7,而健康植物的 CSI 指数值为 1.9...2.5。Wave-LetNN 神经网络消除了植物叶片空间排列、土壤表面凹凸不平和田间个别区域遮光对光反射光谱的影响,将光谱归一化为叶片反射光的总强度。因此,WaveLetNN 神经网络可用作马铃薯植物远程植物检疫监测在线系统的软件核心。
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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