Xing Wei , Jinnuo Zhang , Anna O. Conrad , Charles E. Flower , Cornelia C. Pinchot , Nancy Hayes-Plazolles , Ziling Chen , Zhihang Song , Songlin Fei , Jian Jin
{"title":"Machine learning-based spectral and spatial analysis of hyper- and multi-spectral leaf images for Dutch elm disease detection and resistance screening","authors":"Xing Wei , Jinnuo Zhang , Anna O. Conrad , Charles E. Flower , Cornelia C. Pinchot , Nancy Hayes-Plazolles , Ziling Chen , Zhihang Song , Songlin Fei , Jian Jin","doi":"10.1016/j.aiia.2023.09.003","DOIUrl":null,"url":null,"abstract":"<div><p>Diseases caused by invasive pathogens are an increasing threat to forest health, and early and accurate disease detection is essential for timely and precision forest management. The recent technological advancements in spectral imaging and artificial intelligence have opened up new possibilities for plant disease detection in both crops and trees. In this study, Dutch elm disease (DED; caused by <em>Ophiostoma novo-ulmi,</em>) and American elm (<em>Ulmus americana</em>) was used as example pathosystem to evaluate the accuracy of two in-house developed high-precision portable hyper- and multi-spectral leaf imagers combined with machine learning as new tools for forest disease detection. Hyper- and multi-spectral images were collected from leaves of American elm genotypes with varied disease susceptibilities after mock-inoculation and inoculation with <em>O. novo-ulmi</em> under greenhouse conditions. Both traditional machine learning and state-of-art deep learning models were built upon derived spectra and directly upon spectral image cubes. Deep learning models that incorporate both spectral and spatial features of high-resolution spectral leaf images have better performance than traditional machine learning models built upon spectral features alone in detecting DED. Edges and symptomatic spots on the leaves were highlighted in the deep learning model as important spatial features to distinguish leaves from inoculated and mock-inoculated trees. In addition, spectral and spatial feature patterns identified in the machine learning-based models were found relative to the DED susceptibility of elm genotypes. Though further studies are needed to assess applications in other pathosystems, hyper- and multi-spectral leaf imagers combined with machine learning show potential as new tools for disease phenotyping in trees.</p></div>","PeriodicalId":52814,"journal":{"name":"Artificial Intelligence in Agriculture","volume":"10 ","pages":"Pages 26-34"},"PeriodicalIF":8.2000,"publicationDate":"2023-09-26","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Artificial Intelligence in Agriculture","FirstCategoryId":"1087","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S2589721723000405","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"AGRICULTURE, MULTIDISCIPLINARY","Score":null,"Total":0}
引用次数: 0
Abstract
Diseases caused by invasive pathogens are an increasing threat to forest health, and early and accurate disease detection is essential for timely and precision forest management. The recent technological advancements in spectral imaging and artificial intelligence have opened up new possibilities for plant disease detection in both crops and trees. In this study, Dutch elm disease (DED; caused by Ophiostoma novo-ulmi,) and American elm (Ulmus americana) was used as example pathosystem to evaluate the accuracy of two in-house developed high-precision portable hyper- and multi-spectral leaf imagers combined with machine learning as new tools for forest disease detection. Hyper- and multi-spectral images were collected from leaves of American elm genotypes with varied disease susceptibilities after mock-inoculation and inoculation with O. novo-ulmi under greenhouse conditions. Both traditional machine learning and state-of-art deep learning models were built upon derived spectra and directly upon spectral image cubes. Deep learning models that incorporate both spectral and spatial features of high-resolution spectral leaf images have better performance than traditional machine learning models built upon spectral features alone in detecting DED. Edges and symptomatic spots on the leaves were highlighted in the deep learning model as important spatial features to distinguish leaves from inoculated and mock-inoculated trees. In addition, spectral and spatial feature patterns identified in the machine learning-based models were found relative to the DED susceptibility of elm genotypes. Though further studies are needed to assess applications in other pathosystems, hyper- and multi-spectral leaf imagers combined with machine learning show potential as new tools for disease phenotyping in trees.
入侵病原体引起的疾病对森林健康的威胁越来越大,早期准确的疾病检测对于及时准确的森林管理至关重要。光谱成像和人工智能的最新技术进步为作物和树木的植物病害检测开辟了新的可能性。在这项研究中,荷兰榆树病(DED;由Ophiostoma novo ulmi引起)和美国榆树(Ulmus americana)被用作示例病理系统,以评估两种内部开发的高精度便携式超光谱和多光谱叶片成像仪与机器学习相结合作为森林疾病检测的新工具的准确性。在温室条件下,从具有不同疾病易感性的美国榆树基因型的叶片上采集了模拟接种和接种O.novo ulmi后的超光谱和多光谱图像。传统的机器学习和最先进的深度学习模型都是建立在导出的光谱和直接建立在光谱图像立方体上的。在检测DED时,结合高分辨率光谱叶片图像的光谱和空间特征的深度学习模型比单独基于光谱特征建立的传统机器学习模型具有更好的性能。在深度学习模型中,叶片上的边缘和症状点被强调为区分叶片与接种和模拟接种树木的重要空间特征。此外,在基于机器学习的模型中识别的光谱和空间特征模式与榆树基因型的DED易感性有关。尽管还需要进一步的研究来评估在其他病理系统中的应用,但结合机器学习的超光谱和多光谱叶片成像仪显示出作为树木疾病表型新工具的潜力。