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Constructing segmentation method for wheat powdery mildew using deep learning.

Hecang Zang1,2, Congsheng Wang1, Qing Zhao1,2

  • 1Institute of Agricultural Information Technology, Henan Academy of Agricultural Sciences, Zhengzhou, China.

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Summary

A new RSE-Swin Unet model accurately segments wheat powdery mildew and stripe rust images, improving disease detection for better crop management and food security. This advanced deep learning approach enhances agricultural sustainability.

Keywords:
ResNetSENetSwin-Unetdeep learningwheat powdery mildew

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Area of Science:

  • Agricultural Science
  • Computer Vision
  • Deep Learning

Background:

  • Powdery mildew significantly impacts wheat yield and global food security, necessitating accurate disease detection for sustainable agriculture.
  • Effective segmentation of wheat powdery mildew images is crucial for disease-resistant breeding and precise agricultural control strategies.

Purpose of the Study:

  • To develop an advanced deep learning model for accurate segmentation of wheat powdery mildew and stripe rust images.
  • To address challenges in wheat disease image analysis, including complex lesion morphology and blurred boundaries, using an improved Swin-Unet architecture.

Main Methods:

  • Proposed RSE-Swin Unet, integrating ResNet and SENet modules into the Swin-Unet architecture.
  • Utilized SENet (Squeeze-and-Excitation Network) for enhanced feature extraction and attention.
  • Incorporated ResNet (Residual Network) layers in the bottleneck to improve feature representation.

Main Results:

  • RSE-Swin Unet achieved superior segmentation performance on a self-built wheat powdery mildew dataset, outperforming original Swin-Unet by up to 3.64% in mPA.
  • On a wheat stripe rust dataset, RSE-Swin Unet also demonstrated significant improvements, with MIoU, mPA, and accuracy higher than Swin-Unet by up to 5.38%.
  • The proposed method showed competitive and improved results compared to other mainstream deep learning models like U-Net, PSPNet, and DeepLabV3+.

Conclusions:

  • The RSE-Swin Unet model provides accurate and robust segmentation for wheat powdery mildew and stripe rust images, even in challenging conditions.
  • This method offers significant support for identifying resistance in wheat breeding materials and advancing precise disease management in agriculture.
  • The enhanced computer vision capabilities contribute to improved performance evaluation and disease detection in crop monitoring.