基于改进E-DWT算法和深度学习模型的红小豆锈病诊断方法

doi:10.3964/j.issn.1000-0593(2025)09-2648-10

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摘要：红小豆锈病是一种由真菌引起的常见植物病害，主要通过感染叶片影响光合作用，导致作物产量显著下降。本文提出了一种基于改进经验模态分解-小波变换（E-DWT）算法和深度学习模型的新型红小豆锈病诊断方法。选用“宝清红”红小豆作为实验对象，使用手持可见/近红外光谱仪对960例红小豆叶片进行为期10天的连续光谱数据采集，获取波长范围为326～1 075 nm的红小豆叶片反射率数据。首先，采用改进的E-DWT算法对采集的光谱数据进行去噪处理。该算法结合了经验模态分解（EMD）和小波阈值去噪技术，能够在去除噪声的同时最大限度保留信号的有效信息。通过对比RMSE和SNR指标确定了最佳的小波基函数(sym5)和分解层数(4层)。为了进一步降低高维数据中的冗余信息，采用连续投影算法（SPA）从750个初始波长中筛选出了12个具有代表性的特征波长，实现了数据降维，将特征波长数量减少了98.4%。接着，结合格拉姆角场（GAF）方法，将一维波长序列转换为二维光谱图像，增强了不同波段之间的相关性，便于后续的模型训练。在模型设计上，采用了结合卷积神经网络（CNN）和卷积块注意力机制（CBAM）的深度学习模型。CBAM模块通过引入通道和空间注意力机制，能够有效区分光谱数据中不同特征波长和时间节点的权重，使模型更加关注影响红小豆锈病识别的关键特征。实验结果表明，基于CBAM的CNN模型在训练集中的识别率为99.31%，而在测试集中的识别率为98.33%，召回率达到98.89%，明显高于传统CNN模型的表现。与现有的其他方法相比，本文提出的模型在识别准确性、稳定性以及训练收敛速度上均具有显著优势。总体而言，本文所提出的基于改进E-DWT算法与CBAM-CNN模型的红小豆锈病诊断方法，不仅实现了高效、精准的病害检测，还为未来数据驱动型作物病害诊断系统的构建提供了理论依据与技术支持。

关键词：红小豆锈病；光谱数据处理；E-DWT 算法；深度学习模型；诊断模型

Abstract：Adzuki bean rust is a common fungal disease that significantly reduces crop yield by infecting leaves and impairing photosynthesis. This paper proposes a novel diagnostic method for adzuki bean rust based on an improved Empirical Mode Decomposition-Wavelet Transform (E-DWT) algorithm and a deep learning model. Using “Baoqinghong” adzuki beans as the experimental material, 960 leaf spectral datasets were collected over 10 days using a handheld visible/near-infrared spectrometer, obtaining reflectance data in the wavelength range of 326~1 075 nm. First, the improved E-DWT algorithm was applied for spectral denoising. This algorithm combines Empirical Mode Decomposition (EMD) and wavelet threshold denoising technology to retain effective signal information while removing noise. The optimal wavelet basis function (sym5) and the number of decomposition layers (4 layers) were determined by comparing the RMSE and SNR indicators. To further reduce redundancy in high-dimensional data, the Successive Projections Algorithm (SPA) was employed to select 12 representative wavelengths from the initial 750 features, resulting in a 98.4% reduction in feature wavelength count. Next, the Gramian Angular Field (GAF) method was employed to convert the one-dimensional wavelength sequence into a two-dimensional spectral image, thereby enhancing correlations between different bands for subsequent model training. The designed deep learning model combines a Convolutional Neural Network (CNN) with a Convolutional Block Attention Module (CBAM). The CBAM module effectively discriminates the weights of different feature wavelengths and time nodes through channel and spatial attention mechanisms, enabling the model to focus on key features influencing adzuki bean rust identification. Experimental results show that the CBAM-CNN model achieved 99.31% accuracy in the training set, 98.33% accuracy in the test set, and 98.89% recall, significantly outperforming traditional CNN models. Compared to existing methods, the proposed model exhibits superior performance in terms of recognition accuracy, stability, and training convergence speed. Additionally, the model structure is more concise, which optimizes parameter adjustment and improves operability in practical applications. In conclusion, the proposed diagnostic method based on the improved E-DWT algorithm and CBAM-CNN model not only achieves efficient and precise disease detection but also provides a theoretical foundation and technical support for constructing data-driven crop disease diagnosis systems in the future.

Key words：Adzuki bean rust; Spectral data processing; E-DWT algorithm; Deep learning model; Diagnostic model

收稿日期: 2024-12-13 修订日期: 2025-04-19

中图分类号:

TP391.4

基金资助: 黑龙江省省属本科高校优秀青年教师基础研究支持计划(YQJH2024170)，黑龙江省自然科学基金联合引导项目(LH2024C076)资助

通讯作者: 关海鸥 E-mail: gho123@163.com

作者简介: 付强，1992年生，黑龙江八一农垦大学信息与电气工程学院讲师 e-mail: fuqiang41151003@126.com

引用本文:

付强，关海鸥，李嘉琪. 基于改进E-DWT算法和深度学习模型的红小豆锈病诊断方法[J]. 光谱学与光谱分析, 2025, 45(09): 2648-2657.
FU Qiang, GUAN Hai-ou, LI Jia-qi. A Diagnostic Method for Adzuki Bean Rust Based on an Improved E-DWT Algorithm and Deep Learning Model. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2648-2657.

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