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一种基于人工智能预训练模型的、利用胸部X光图像的新冠病毒检测模型。

An AI-enabled pre-trained model-based Covid detection model using chest X-ray images.

作者信息

Gupta Rajeev Kumar, Kunhare Nilesh, Pathik Nikhlesh, Pathik Babita

机构信息

Pandit Deendayal Energy University, Gandhinagar, India.

Amity University, Gwalior, India.

出版信息

Multimed Tools Appl. 2022;81(26):37351-37377. doi: 10.1007/s11042-021-11580-x. Epub 2022 Jul 12.

DOI:10.1007/s11042-021-11580-x
PMID:35844979
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9273923/
Abstract

The year 2020 and 2021 was the witness of Covid 19 and it was the leading cause of death throughout the world during this time period. It has an impact on a large geographic area, particularly in countries with a large population. Due to the fact that this novel coronavirus has been detected in all countries around the world, the World Health Organization (WHO) has declared Covid-19 to be a pandemic. This novel coronavirus spread quickly from person to person through the saliva droplets and direct or indirect contact with an infected person. The tests carried out to detect the Covid-19 are time-consuming and the primary cause of rapid growth in Covid19 cases. Early detection of Covid patient can play a significant role in controlling the Covid chain by isolation the patient and proper treatment at the right time. Recent research on Covid-19 claim that Chest CT and X-ray images can be used as the preliminary screening for Covid-19 detection. This paper suggested an Artificial Intelligence (AI) based approach for detecting Covid-19 by using X-ray and CT scan images. Due to the availability of the small Covid dataset, we are using a pre-trained model. In this paper, four pre-trained models named VGGNet-19, ResNet50, InceptionResNetV2 and MobileNet are trained to classify the X-ray images into the Covid and Normal classes. A model is tuned in such a way that a smaller percentage of Covid cases will be classified as Normal cases by employing normalization and regularization techniques. The updated binary cross entropy loss (BCEL) function imposes a large penalty for classifying any Covid class to Normal class. The experimental results reveal that the proposed InceptionResNetV2 model outperforms the other pre-trained model with training, validation and test accuracy of 99.2%, 98% and 97% respectively.

摘要

2020年和2021年见证了新冠疫情,在此期间它是全球主要的死亡原因。它影响范围广泛,尤其是在人口众多的国家。由于在世界各国都检测到了这种新型冠状病毒,世界卫生组织(WHO)已宣布新冠疫情为大流行病。这种新型冠状病毒通过唾液飞沫以及与感染者的直接或间接接触在人与人之间迅速传播。用于检测新冠病毒的测试耗时较长,这也是新冠病例快速增长的主要原因。早期发现新冠患者对于通过隔离患者并在合适时间进行恰当治疗来控制新冠传播链具有重要作用。最近关于新冠病毒的研究表明,胸部CT和X射线图像可用于新冠病毒检测的初步筛查。本文提出了一种基于人工智能(AI)的方法,通过使用X射线和CT扫描图像来检测新冠病毒。由于新冠数据集较小,我们使用了预训练模型。在本文中,对四个名为VGGNet - 19、ResNet50、InceptionResNetV2和MobileNet的预训练模型进行训练,以将X射线图像分类为新冠和正常两类。通过采用归一化和正则化技术对模型进行调整,使得将较小比例的新冠病例误分类为正常病例。更新后的二元交叉熵损失(BCEL)函数对于将任何新冠类别误分类为正常类别会施加较大惩罚。实验结果表明,所提出的InceptionResNetV2模型优于其他预训练模型,其训练、验证和测试准确率分别为99.2%、98%和97%。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9210/9273923/e8d897488119/11042_2021_11580_Fig9_HTML.jpg
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