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CASM-AMFMNet:一种基于坐标注意力洗牌机制和非对称多尺度融合模块的葡萄叶病害分类网络。

CASM-AMFMNet: A Network Based on Coordinate Attention Shuffle Mechanism and Asymmetric Multi-Scale Fusion Module for Classification of Grape Leaf Diseases.

作者信息

Suo Jiayu, Zhan Jialei, Zhou Guoxiong, Chen Aibin, Hu Yaowen, Huang Weiqi, Cai Weiwei, Hu Yahui, Li Liujun

机构信息

College of Computer and Information Engineering, Central South University of Forestry and Technology, Changsha, China.

Plant Protection Research Institute, Hunan Academy of Agricultural Sciences (HNAAS), Changsha, China.

出版信息

Front Plant Sci. 2022 May 24;13:846767. doi: 10.3389/fpls.2022.846767. eCollection 2022.

DOI:10.3389/fpls.2022.846767
PMID:35685012
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9171378/
Abstract

Grape disease is a significant contributory factor to the decline in grape yield, typically affecting the leaves first. Efficient identification of grape leaf diseases remains a critical unmet need. To mitigate background interference in grape leaf feature extraction and improve the ability to extract small disease spots, by combining the characteristic features of grape leaf diseases, we developed a novel method for disease recognition and classification in this study. First, Gaussian filters Sobel smooth de-noising Laplace operator (GSSL) was employed to reduce image noise and enhance the texture of grape leaves. A novel network designated coordinated attention shuffle mechanism-asymmetric multi-scale fusion module net (CASM-AMFMNet) was subsequently applied for grape leaf disease identification. CoAtNet was employed as the network backbone to improve model learning and generalization capabilities, which alleviated the problem of gradient explosion to a certain extent. The CASM-AMFMNet was further utilized to capture and target grape leaf disease areas, therefore reducing background interference. Finally, Asymmetric multi-scale fusion module (AMFM) was employed to extract multi-scale features from small disease spots on grape leaves for accurate identification of small target diseases. The experimental results based on our self-made grape leaf image dataset showed that, compared to existing methods, CASM-AMFMNet achieved an accuracy of 95.95%, F1 score of 95.78%, and mAP of 90.27%. Overall, the model and methods proposed in this report could successfully identify different diseases of grape leaves and provide a feasible scheme for deep learning to correctly recognize grape diseases during agricultural production that may be used as a reference for other crops diseases.

摘要

葡萄病害是导致葡萄产量下降的一个重要因素,通常首先影响叶片。高效识别葡萄叶片病害仍然是一个关键的未满足需求。为了减少葡萄叶片特征提取中的背景干扰并提高提取小病害斑点的能力,结合葡萄叶片病害的特征,我们在本研究中开发了一种新的病害识别与分类方法。首先,采用高斯滤波器-索贝尔平滑去噪-拉普拉斯算子(GSSL)来降低图像噪声并增强葡萄叶片的纹理。随后,应用一种名为协调注意力洗牌机制-不对称多尺度融合模块网络(CASM-AMFMNet)的新型网络进行葡萄叶片病害识别。采用CoAtNet作为网络主干以提高模型学习和泛化能力,这在一定程度上缓解了梯度爆炸问题。进一步利用CASM-AMFMNet来捕捉和定位葡萄叶片病害区域,从而减少背景干扰。最后,采用不对称多尺度融合模块(AMFM)从葡萄叶片上的小病害斑点中提取多尺度特征,以准确识别小目标病害。基于我们自制葡萄叶片图像数据集的实验结果表明,与现有方法相比,CASM-AMFMNet的准确率达到95.95%,F1分数为95.78%,平均精度均值为90.27%。总体而言,本报告中提出的模型和方法能够成功识别葡萄叶片的不同病害,并为深度学习在农业生产中正确识别葡萄病害提供了一种可行方案,可为其他作物病害识别提供参考。

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