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使用大规模CT扫描和X射线图像数据集检测新冠肺炎和肺炎的深度学习集成框架模型的设计与分析

Design and Analysis of a Deep Learning Ensemble Framework Model for the Detection of COVID-19 and Pneumonia Using Large-Scale CT Scan and X-ray Image Datasets.

作者信息

Xue Xingsi, Chinnaperumal Seelammal, Abdulsahib Ghaida Muttashar, Manyam Rajasekhar Reddy, Marappan Raja, Raju Sekar Kidambi, Khalaf Osamah Ibrahim

机构信息

Fujian Provincial Key Laboratory of Big Data Mining and Applications, Fujian University of Technology, Fuzhou 350011, China.

Department of Computer Science and Engineering, Solamalai College of Engineering, Madurai 625020, Tamil Nadu, India.

出版信息

Bioengineering (Basel). 2023 Mar 16;10(3):363. doi: 10.3390/bioengineering10030363.

DOI:10.3390/bioengineering10030363
PMID:36978754
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10045423/
Abstract

Recently, various methods have been developed to identify COVID-19 cases, such as PCR testing and non-contact procedures such as chest X-rays and computed tomography (CT) scans. Deep learning (DL) and artificial intelligence (AI) are critical tools for early and accurate detection of COVID-19. This research explores the different DL techniques for identifying COVID-19 and pneumonia on medical CT and radiography images using ResNet152, VGG16, ResNet50, and DenseNet121. The ResNet framework uses CT scan images with accuracy and precision. This research automates optimum model architecture and training parameters. Transfer learning approaches are also employed to solve content gaps and shorten training duration. An upgraded VGG16 deep transfer learning architecture is applied to perform multi-class classification for X-ray imaging tasks. Enhanced VGG16 has been proven to recognize three types of radiographic images with 99% accuracy, typical for COVID-19 and pneumonia. The validity and performance metrics of the proposed model were validated using publicly available X-ray and CT scan data sets. The suggested model outperforms competing approaches in diagnosing COVID-19 and pneumonia. The primary outcomes of this research result in an average F-score (95%, 97%). In the event of healthy viral infections, this research is more efficient than existing methodologies for coronavirus detection. The created model is appropriate for recognition and classification pre-training. The suggested model outperforms traditional strategies for multi-class categorization of various illnesses.

摘要

最近,已经开发出了各种方法来识别新冠病毒感染病例,比如聚合酶链反应(PCR)检测以及胸部X光和计算机断层扫描(CT)扫描等非接触式检测手段。深度学习(DL)和人工智能(AI)是早期准确检测新冠病毒的关键工具。本研究探索了使用ResNet152、VGG16、ResNet50和DenseNet121等不同的深度学习技术,在医学CT和X光图像上识别新冠病毒感染和肺炎的方法。ResNet框架能准确且精确地使用CT扫描图像。本研究实现了最优模型架构和训练参数的自动化。还采用迁移学习方法来解决内容空白并缩短训练时长。一种升级后的VGG16深度迁移学习架构被应用于X光成像任务的多类别分类。事实证明,增强后的VGG16能以99%的准确率识别三种类型的X光图像,这三种图像是新冠病毒感染和肺炎的典型图像。所提出模型的有效性和性能指标通过公开可用的X光和CT扫描数据集进行了验证。所建议的模型在诊断新冠病毒感染和肺炎方面优于其他竞争方法。本研究的主要成果是平均F值达到了(95%,97%)。在健康病毒感染的情况下,本研究在检测冠状病毒方面比现有方法更有效。所创建的模型适用于识别和分类预训练。所建议的模型在对各种疾病进行多类别分类方面优于传统策略。

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