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Optimized encoder-decoder cascaded deep convolutional network for leaf disease image segmentation.

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Plant leaf infected spot segmentation using robust encoder-decoder cascaded deep learning model.

David Femi1, Manapakkam Anandan Mukunthan1

  • 1Research Scholar, Professor Department of Computer Science & Engineering, Vel Tech Rangarajan Dr. Sagunthala R&D Institute of Science and Technology, Chennai, Tamil Nadu, India.

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Summary
This summary is machine-generated.

A new Deep Encoder-Decoder Cascaded Network (DEDCNet) precisely segments diseased leaf spots, improving plant disease diagnosis. This advanced model enhances agricultural output by accurately identifying and classifying various leaf infections.

Keywords:
Crop leaf disease classificationPyramid poolingSVMdeep learningencoder-decoder networkmulti-scale dilated convolution kernelsegmentation

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Area of Science:

  • Agricultural Science
  • Computer Vision
  • Machine Learning

Background:

  • Accurate leaf disease diagnosis is crucial for agricultural productivity and cost reduction.
  • Inaccurate segmentation of diseased leaf spots can lead to misclassification of plant diseases.
  • Overlapping disease features and dimensions pose challenges for precise segmentation.

Purpose of the Study:

  • To propose a novel Deep Encoder-Decoder Cascaded Network (DEDCNet) for precise leaf image segmentation.
  • To accurately segment diseased leaf spots and differentiate between similar plant diseases.
  • To improve the overall accuracy of leaf disease classification and diagnosis.

Main Methods:

  • Developed a DEDCNet model comprising an Infected Spot Recognition Network (ISRN) and an Infected Spot Segmentation Network (ISSN).
  • ISRN integrates cascaded Convolutional Neural Networks (CNNs) with Feature Pyramid Pooling for infected spot identification.
  • ISSN utilizes an encoder-decoder architecture with multi-scale dilated convolutions for precise segmentation.
  • Employed pre-learned CNNs for texture feature extraction and Support Vector Machine (SVM) for disease classification.

Main Results:

  • Achieved 94.89% accuracy on the Betel Leaf Image dataset with high precision, recall, and F-score.
  • Demonstrated low under-segmentation (6.2%) and over-segmentation (2.8%) rates on the Betel Leaf dataset.
  • Attained 96.5% accuracy on the PlantVillage dataset, outperforming existing models.
  • Achieved Dice coefficients of 0.9822 and 0.9834 on respective datasets in under 0.1 seconds.

Conclusions:

  • The DEDCNet model significantly improves leaf disease segmentation and classification accuracy.
  • The proposed method offers greater efficiency compared to existing models for plant disease analysis.
  • Accurate segmentation is vital for reliable disease diagnosis, contributing to better agricultural outcomes.