Detection of fusarium wilt-induced physiological impairment in strawberry plants using hyperspectral imaging and machine learning

IF 5.4 2区农林科学 Q1 AGRICULTURE, MULTIDISCIPLINARY

Precision Agriculture Pub Date : 2024-07-24 DOI:10.1007/s11119-024-10173-6

P. Castro-Valdecantos, G. Egea, C. Borrero, M. Pérez-Ruiz, M. Avilés

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Abstract

Strawberry (Fragraria x ananassa) is a crop affected by various soil-borne fungal pathogens with mostly non-specific foliar symptoms and often requiring laboratory isolation for correct diagnosis. Moreover, these nonspecific foliar symptoms, appreciated by the human eye, appear after some time following infection by the pathogen. Early detection of plant diseases is one of the primary objectives in agriculture because it may contribute to identifying more tolerant cultivars in breeding programs and optimise pesticide use in agricultural production with earlier applications in emerging disease foci. New technologies, such as remote sensing and machine learning (ML) algorithms, have arisen as potential tools to improve the ability to detect and classify different crop diseases. The combined use of hyperspectral imagery and ML algorithms were investigated to detect and classify the physiological stress caused by early infections of Fusarium wilt in strawberry plants. Six ML models, namely artificial neural network, decision tree, K-nearest neighbour, support vector machine, multinomial logistic regression and Naïve Bayes were developed to estimate physiological stress associated with Fusarium wilt disease. The results showed that stomatal conductance (g_s) and photosynthesis (A) declined even without visual symptoms of the disease. Among the six ML models evaluated, the artificial neural network model showed the highest classification performance with an overall accuracy of 81%, regardless of the physiological parameter utilized for model training. Moreover, the artificial neural network accurately predicted the absolute values of both physiological parameters (g_s and A) based on the complete spectral signature from visually healthy foliar tissue, achieving coefficients of determination of 84% and 81%, respectively. Consequently, ML models utilizing physiological response data and hyperspectral imaging exhibited remarkable robustness, facilitating the estimation of Fusarium wilt severity in strawberry plants even without visual symptoms.

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利用高光谱成像和机器学习检测枯萎镰刀菌诱发的草莓植株生理损伤

草莓（Fragraria x ananassa）是一种受各种土传真菌病原体影响的作物，其叶片症状大多是非特异性的，通常需要进行实验室分离才能做出正确诊断。此外，这些非特异性的叶面症状在病原体感染一段时间后才会出现，人眼难以察觉。植物病害的早期检测是农业的主要目标之一，因为这有助于在育种计划中确定更耐受的栽培品种，并在农业生产中优化杀虫剂的使用，更早地应用于新出现的病害疫点。遥感和机器学习（ML）算法等新技术已成为提高检测和分类不同作物病害能力的潜在工具。研究人员结合使用高光谱图像和 ML 算法，对草莓植株早期感染镰刀菌枯萎病造成的生理压力进行了检测和分类。开发了六种 ML 模型，即人工神经网络、决策树、K-近邻、支持向量机、多项式逻辑回归和奈夫贝叶斯模型，以估计与镰刀菌枯萎病相关的生理压力。结果表明，即使没有直观的病害症状，气孔导度（gs）和光合作用（A）也会下降。在评估的六个 ML 模型中，人工神经网络模型的分类性能最高，总体准确率达 81%，而与模型训练中使用的生理参数无关。此外，人工神经网络根据视觉健康叶片组织的完整光谱特征，准确预测了两个生理参数（gs 和 A）的绝对值，确定系数分别达到 84% 和 81%。因此，利用生理响应数据和高光谱成像的 ML 模型表现出显著的鲁棒性，即使在没有视觉症状的情况下，也能帮助估计草莓植株镰刀菌枯萎病的严重程度。

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来源期刊

Precision Agriculture 农林科学-农业综合

CiteScore

12.30

自引率

8.10%

发文量

103

审稿时长

>24 weeks

期刊介绍： Precision Agriculture promotes the most innovative results coming from the research in the field of precision agriculture. It provides an effective forum for disseminating original and fundamental research and experience in the rapidly advancing area of precision farming. There are many topics in the field of precision agriculture; therefore, the topics that are addressed include, but are not limited to: Natural Resources Variability: Soil and landscape variability, digital elevation models, soil mapping, geostatistics, geographic information systems, microclimate, weather forecasting, remote sensing, management units, scale, etc. Managing Variability: Sampling techniques, site-specific nutrient and crop protection chemical recommendation, crop quality, tillage, seed density, seed variety, yield mapping, remote sensing, record keeping systems, data interpretation and use, crops (corn, wheat, sugar beets, potatoes, peanut, cotton, vegetables, etc.), management scale, etc. Engineering Technology: Computers, positioning systems, DGPS, machinery, tillage, planting, nutrient and crop protection implements, manure, irrigation, fertigation, yield monitor and mapping, soil physical and chemical characteristic sensors, weed/pest mapping, etc. Profitability: MEY, net returns, BMPs, optimum recommendations, crop quality, technology cost, sustainability, social impacts, marketing, cooperatives, farm scale, crop type, etc. Environment: Nutrient, crop protection chemicals, sediments, leaching, runoff, practices, field, watershed, on/off farm, artificial drainage, ground water, surface water, etc. Technology Transfer: Skill needs, education, training, outreach, methods, surveys, agri-business, producers, distance education, Internet, simulations models, decision support systems, expert systems, on-farm experimentation, partnerships, quality of rural life, etc.