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Related Experiment Video

Updated: Jun 2, 2025

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Enhanced Pneumonia Detection in Chest X-Rays Using Hybrid Convolutional and Vision Transformer Networks.

Benzorgat Mustapha1, Yatong Zhou1, Chunyan Shan2

  • 1School of Electronics and Information Engineering, Hebei University of Technology, Tianjin 300401, China.

Current Medical Imaging
|January 14, 2025
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Summary
This summary is machine-generated.

A new hybrid deep learning model combining Convolutional Neural Networks (CNNs) and Swin Transformers significantly improves pneumonia detection in X-rays. This accurate and robust AI tool offers potential for accessible diagnostics in underserved regions.

Keywords:
CLAHEChest X-ray imaging.Computer-aided diagnosisConvolutional neural networksDeep learningHyperparameter optimizationMedical image processingPneumonia detectionSwin transformerVision transformers

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Area of Science:

  • Medical Imaging Analysis
  • Artificial Intelligence in Healthcare
  • Deep Learning for Diagnostics

Background:

  • Pneumonia detection from chest X-rays is crucial for timely treatment.
  • Existing diagnostic methods face limitations, especially in resource-constrained areas.
  • Deep learning offers promising avenues for automated and accurate image analysis.

Purpose of the Study:

  • To develop and evaluate a novel hybrid deep learning model for enhanced pneumonia detection in chest X-rays.
  • To improve diagnostic accuracy and reduce misclassifications compared to traditional methods.
  • To create a robust and deployable solution for regions with limited access to healthcare.

Main Methods:

  • A hybrid model integrating Convolutional Neural Networks (CNNs) with modified Swin Transformer blocks was developed.
  • CNN layers extracted local features, while Swin Transformers captured global context via window-based self-attention.
  • Image preprocessing included resizing and CLAHE; data augmentation and Bayesian optimization (Optuna) were used for robustness and fine-tuning.

Main Results:

  • The hybrid model achieved 98.72% accuracy and a low loss of 0.064 on an unseen dataset.
  • It significantly outperformed a baseline CNN model across all metrics, including precision (0.9738 normal, 1.0000 pneumonia) and F1-score (0.9872).
  • Confusion matrices indicated high sensitivity and specificity, with minimal misclassifications.

Conclusions:

  • The hybrid CNN-ViT model effectively captures both local and global features in X-rays, leading to superior pneumonia detection performance.
  • Its lightweight design facilitates deployment in resource-limited settings, potentially improving patient outcomes globally.
  • Future work includes model refinement, advanced image processing, and explainable AI integration.