摘要
中国水稻种植受稻瘟病影响面临严重威胁,传统的人工检测方法已难以满足现代农业对精准预测和预报的需求,亟需对水稻病害诊断技术进行创新与优化,以利用深度学习技术实现水稻稻瘟病早期分级检测。该研究针对水稻抗性筛选的苗期试验,基于无人机航拍图像构建了稻瘟病图像数据集,并提出了一种改进的GoogLeNet深度学习模型。通过在原始GoogLeNet模型中引入基于病斑颜色的注意力模块,增强了模型对稻瘟病特征的识别能力。试验结果显示,改进后的模型在精确率、召回率和F1得分上分别比原始模型提高了15.33、15.80和15.61个百分点。与AlexNet、ResNet和VGG等分类模型相比,改进后的GoogLeNet模型在稻瘟病分类任务中表现更为优越,精确率达到了84.23%,比其他分类模型分别高出16.11、17.20和25.95个百分点。该模型在保持高效检测速度的同时,显著提升了检测精度,为新品种稻瘟病抗性筛选提供了重要参考。
Rice is one of the most crucial crops worldwide in modern agriculture.The current diseases(such as rice blasts)have seriously threatened the superior quality and yield of the rice in recent years.However,manual disease monitoring cannot fully meet the large-scale rice cultivation in the extensive fields.Furthermore,the mechanical equipment for disease detection can frequently cause unnecessary harm to the rice plants.As a result,it is highly required for the intelligent and large-scale detection of diseases to reduce the labor costs for the high precision of monitoring.Deep learning models(such as GoogLeNet)can be expected to accurately identify the rice blast.Nevertheless,an optimal balance between detection accuracy and processing speed is very necessary for GoogLeNet in the practical applications of rice blast detection.This study aims to classify and detect the rice blast diseases at the seedling stage using an improved GoogLeNet model.Particularly,the rice was vulnerable to diseases during the tillering stage.Specifically,the research targets were also collected from the rice images in the critical period.The disease features were determined to significantly influence the subsequent rice growth using refined models.Several key steps were also involved:Initially,a comprehensive and diverse dataset of rice blast images was obtained after field research,expert consultations,and advanced techniques of image capture,followed by image processing.Subsequently,data augmentation(including rotation and brightness adjustments)was employed to obtain the final dataset with 2000 rice blast images.An attention mechanism was then integrated into the GoogLeNet model.The distinct features of rice blasts were focused on after optimization.An ablation test was conducted to assess the effectiveness of the improved model.Comparative experiments were also performed to illustrate its advantages.The results indicated that this modification significantly improved the detection accuracy.Specifically,the attention mechanism module(GoogLeNet+DSCAM)was incorporated to increase the recall by 9.29 percentage points,compared with the original model.The attention mechanism has effectively enhanced the detection of critical information.Furthermore,the improved GoogLeNet model also surpassed the original model,in terms of all evaluation metrics.The better performance was achieved to improve by 15.33 percentage points in the precision,with significant gains also observed in recall and F1 score,Thereby the refined network architecture substantially enhanced the detection performance.The superiority of the improved GoogLeNet was observed in the tasks of rice blast classification.Several widely-recognized classification models(including AlexNet,ResNet,VGG,and the original GoogLeNet)were selected as the benchmarks for comparison.The rice blast datasets and an independent test set were utilized to fully train and then evaluate these models.Meanwhile,the comparative analysis showed that there were distinct advantages and practical efficacy of the improved GoogLeNet model.Such classification also demonstrated some challenges.The enhanced GoogLeNet model exhibited exceptional performance overall evaluation metrics,indicating a marked superiority over AlexNet,ResNet,VGG,and the original GoogLeNet.Specifically,the notable improvements were also achieved by 16.11 percentage-point improvement in precision compared to AlexNet and a 15.33 percentage-point improvement compared to the original GoogLeNet,with significant enhancements also observed in recall and F1 score.These significant performances can provide high efficacy to enhance the accuracy and the efficient speed of the detection.This finding can also offer valuable insights into preventing and controlling rice diseases.
作者
彭慧琳
李东晖
陈兆中
肖应辉
李绪孟
PENG Huilin;LI Donghui;CHEN Zhaozhong;XIAO Yinghui;LI Xumeng(College of Information and Intelligent Science and Technology,Hunan Agricultural University,Changsha 410128,China;College of Agronomy,Hunan Agricultural University,Changsha 410128,China)
出处
《农业工程学报》
北大核心
2025年第10期204-211,共8页
Transactions of the Chinese Society of Agricultural Engineering
基金
湖南省自然科学基金项目(2024JJ7227)
湖南省重点研发计划项目(2022NK2047)
创新平台与人才计划-农村科技特派员(2022NK4167)。
