基于深度学习的槟榔黄化病感病植株无人机遥感精准识别OA
Precision identification of arecanut yellowing disease infected plants using UAV remote sensing and deep learning
槟榔黄化病是一种严重危害槟榔生长的系统性病害,实现感病植株的精准监测对于槟榔产业的可持续发展至关重要.针对当前槟榔黄化病感病植株无人机遥感识别精度较低,易受变色灌木等相似地物目标干扰的问题.该研究基于无人机搭载RedEdge-M多光谱相机所获得的5波段多光谱遥感影像数据,通过计算欧式距离和J-M(Jeffreys-Matusita)距离,结合可分性分析提取敏感光谱指标;基于影像标准化预处理、样本切片及人工核验筛选构建标准化检测数据集,共获取18 520个高质量样本,按照8∶1∶1的比例划分训练集、验证集与测试集,之后通过改进YOLO(You Only Look Once)v10算法获取感病植株精准识别模型.模型在主干网络中引入GhostNet以增强关键波段的有效信息表达并提升对细粒度病征纹理的建模能力,采用双向特征金字塔网络(bidirectional feature pyramid network,BiFPN)强化复杂林分环境下的多尺度特征聚合效果,引入形状感知型交并比(shape-aware intersection over union,SIoU),通过边界框回归机制提高病株定位精度.结果表明,改进YOLOv10模型跨尺度特征融合能力增强使mAP@0.5提升至90.6%,相较于相较于最优基线模型YOLOv10提升了4.5个百分点;精准率为91.2%,召回率为92.7%,均优于其他经典深度学习模型.该模型实现了对槟榔黄化病感病植株的快速、准确检测,可满足槟榔黄化病巡查与监测的实际应用需求.
Areca nut yellowing disease is one of the systemic diseases that severely threaten the growth of Areca catechu palms.It is crucial to precisely monitor the infected plants in the sustainable areca nut industry.Conventional monitoring has relied primarily on visual inspection and manual surveys.It is often required for the efficient operation under the frequent cloudy and rainy weather in Hainan Province,China.Unmanned Aerial Vehicle(UAV)remote sensing can be expected to serve as an effective solution for the high quality and availability of satellite optical imagery,due to the high spatial resolution,flexible response,and low costs.However,several limitations are still suffered from the monitoring of areca yellowing diseases,including the low identification accuracy and significant interference from similar ground objects,such as the discolored shrubs.This study aims to identify the areca nut yellowing disease-infected plants using UAV remote sensing and deep learning.Field sampling was also performed to assess the disease severity of Areca catechu palms,according to the disease features and the separability in the remote sensing imagery.Subsequently,a MicaSense RedEdge-M multispectral camera on a DJI Phantom 4 Pro V2.0 UAV was employed to acquire 5-band multispectral imagery,including the blue,green,red,near-infrared,and red-edge bands.Euclidean and Jeffreys-Matusita(J-M)distances were calculated to extract the sensitive spectral indices with high separability.Four datasets were constructed to train the typical models.A standardized dataset was then established from a total of 18,520 high-quality samples after image preprocessing,sample slicing,and manual verification.This final dataset was partitioned into training,validation,and test sets at a ratio of 8∶1∶1.A series of target improvements were implemented using the YOLO(You Only Look Once)v10 algorithm.A precise model was developed to identify the infected plants.Firstly,the lightweight GhostNet model was incorporated into the backbone network.The feature generation was enhanced to represent the effective information from the key multispectral bands.A redundant feature was reduced for the fine-grained disease textures.Secondly,a bidirectional feature pyramid network(BiFPN)was employed to replace the parts of the original structure at the feature fusion stage.Its learnable weights and bidirectional cross-scale fusion strengthened the multi-scale feature aggregation after modification,particularly in the complex forest stands.Finally,the Shape-aware intersection over union(SIoU)Loss function was introduced into the regression branch of the detection head.A more stable and geometrically constrained bounding box regression improved the localization accuracy of infected plants to accelerate the convergence of the model.The results demonstrate that the enhanced cross-scale feature fusion of the improved YOLOv10 model increased the mAP@0.5 to 90.6%,which was improved by approximately 20%,compared with the common models,such as Faster R-CNN,YOLOv8,and YOLOv10.Furthermore,the better performance was achieved in a precision of 91.2%and a recall of 92.7%,both of which significantly outperformed the classic deep learning models.The rapid and accurate detection of areca catechu plants infected with yellowing disease can be expected to effectively meet the practical demands for the inspection and monitoring of the disease.
侯瑞;张弼尧;徐少雄;董莹莹
遥感与数字地球全国重点实验室,中国科学院空天信息创新研究院,北京 100101||海南省地球观测重点实验室,海南空天信息研究院,文昌 571300||中国科学院大学,北京 100049遥感与数字地球全国重点实验室,中国科学院空天信息创新研究院,北京 100101||海南省地球观测重点实验室,海南空天信息研究院,文昌 571300遥感与数字地球全国重点实验室,中国科学院空天信息创新研究院,北京 100101||中国城市规划设计研究院,北京 100044遥感与数字地球全国重点实验室,中国科学院空天信息创新研究院,北京 100101
农业科技
无人机遥感多光谱影像深度学习特征增强精准识别槟榔黄化病
UAVremote sensingmultispectral imagerydeep learningfeature enhancementprecision identificationareca nut yellowing disease
《农业工程学报》 2026 (9)
250-258,9
海南省自然科学基金青年基金项目(322QN346)
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