| 基于改进DenseNet的茶叶病害小样本识别方法 |
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| 引用本文: | 李子茂,徐杰,郑禄,帖军,于舒.基于改进DenseNet的茶叶病害小样本识别方法[J].农业工程学报,2022,38(10):182-190. |
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| 作者姓名: | 李子茂 徐杰 郑禄 帖军 于舒 |
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| 作者单位: | 1. 中南民族大学计算机科学学院,武汉 430074;2. 湖北省制造企业智能管理工程技术研究中心,武汉 430074 |
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| 基金项目: | 湖北省技术创新专项重大项目(2019ABA101);湖北省科技重大专项(2020AEA011);武汉市科技计划应用基础前沿项目(2020020601012267) |
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| 摘 要: | 针对茶叶病害识别的传统方法费工费时,同时由于茶叶病害样本小且分布不均导致传统卷积神经网络不能准确快速识别的问题,提出一种基于迁移学习的SE-DenseNet-FL茶叶病害识别方法。SE-DenseNet-FL以DenseNet模型为基础,首先在DenseNet网络结构中融入SENet(Squeeze-and-Excitation Networks)模块,以加强重要特征传播实现特征重标定;其次引入Focal Loss函数替换原DenseNet中的损失函数,使模型在训练时专注于难分类的样本,以缓解样本分布不均给模型带来的性能影响;最后利用PlantVillage数据集预训练取得预训练模型,通过迁移学习在预训练模型上使用自建茶叶病害数据集进行参数微调,以缓解样本数据过少带来的过拟合影响。通过与原模型DenseNet以及其他经典分类模型(AlexNet、VGG16、ResNet101)进行试验对比,结果表明基于迁移学习的SE-DenseNet-FL在小样本及样本分布不均情景下对茶叶病害的识别准确率达到92.66%。该模型具有较高的识别准确率与较强的鲁棒性,可为茶叶病害智能诊断提供参考。
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| 关 键 词: | 茶叶 病害 迁移学习 图像识别 DenseNet |
| 收稿时间: | 2021/10/10 0:00:00 |
| 修稿时间: | 2022/5/11 0:00:00 |
Small sample recognition method of tea disease based on improved DenseNet |
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| Li Zimao,Xu Jie,Zheng Lu,Tie Jun,Yu Shu.Small sample recognition method of tea disease based on improved DenseNet[J].Transactions of the Chinese Society of Agricultural Engineering,2022,38(10):182-190. |
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| Authors: | Li Zimao Xu Jie Zheng Lu Tie Jun Yu Shu |
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| Institution: | 1. College of Computer Science, South-Central University for Nationalities, Wuhan 430074, China; 2. Hubei Provincial Engineering Research Center for Intelligent Management of Manufacturing Enterprises, Wuhan 430074, China |
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| Abstract: | Abstract: More than two million tons of tea can be produced each year in China. Tea production, consumption, and exportation have been dominated for decades in the world. However, some diseases in the growing period of tea plants have posed a serious impact on both tea yields and quality in recent years, even leading to serious economic loss. It is a high demand for the accurate identification and treatment of tea diseases for the higher production and quality. In traditional, various tea diseases can be generally identified by the accumulated experiences from experts, indicating the seriously labor-intensive and time-consuming. Since the conventional convolutional neural networks (CNN) have been ever applied to the plant disease identification, the accuracy and efficiency can drop dramatically for the small number of disease samples and uneven distribution. In this study, a transfer learning (called SE-DenseNet-FL model) was proposed for the tea disease identification of small samples. The Squeeze-and-Excitation Networks (SENet) module was first integrated into the DenseNet network structure. Among them, the SENet was used to compress the feature channels for the much more global receptive fields. As such, the SE-DenseNet-FL model was strengthened to propagate the important features for the second calibration. The Focal Loss function was then introduced to replace the loss function in the original DenseNet. Thus, the SE-DenseNet-FL model was guided to focus on the hard-to-classify samples during training, thereby alleviating the impact of the uneven sample distribution on the performance of the model. Finally, a pre-training model was obtained to pre-train with the PlantVillage dataset. A self-developed dataset of tea disease was used to fine-tune the parameters of the pre-training model through transfer learning, thereby alleviating the over-fitting from the small sample data. The dataset was taken from the organic tea garden base of Wantanhe Village, Wuyang Town, Hefeng obtains County, Enshi Tujia, and Miao Autonomous Prefecture, Hubei Province, China. A total of 2175 disease images were captured to involve the five kinds of diseases of three tea varieties, including Zhongcha No. 108, Echa No. 1, and Hefeng Dadou Tea. Five diseases included the white star disease, tea wheel spot disease, tea coal disease, tea round red spot disease, and tea leaf blight. Subsequently, an experimental operating system (CentOS) was adopted to verify the model, where a Pytorch framework was used to implement all the code and the CUDA10.0 parallel computing framework for the acceleration. A series of experiments were conducted in the field environment. Firstly, the model was optimized for the learning rate. The optimal learning rate of 0.001 was achieved, where the initial learning rates were set as 0.000 1, 0.001, 0.01, and 0.1. Then, the new transfer learning models were performed on the tea disease images. Correspondingly, transfer learning can be expected to effectively alleviate the over-fitting for the better generalization of the model. Finally, an experiment was also designed to compare with the original DenseNet model and three classic classification models as AlexNet, VGG16, and ResNet101. Consequently, the SE-DenseNet-FL model using transfer learning can be used to identify the tea diseases with an accuracy of 92.66% in the case of small samples and uneven sample distribution, indicating higher recognition accuracy and stronger robustness. The finding can provide a strong reference for the intelligent diagnosis of tea diseases. |
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| Keywords: | tea diseases transfer learning image recognition DenseNet |
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