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基于混合正弦余弦和极限学习机的深度卷积神经网络用于从X射线图像中实时诊断COVID-19的研究进展

Evolving deep convolutional neutral network by hybrid sine-cosine and extreme learning machine for real-time COVID19 diagnosis from X-ray images.

作者信息

Wu Chao, Khishe Mohammad, Mohammadi Mokhtar, Taher Karim Sarkhel H, Rashid Tarik A

机构信息

Department of Radiology, The First Affiliated Hospital of Chongqing Medical University, Chongqing, China.

Corresponding Author, Imam Khomeini Marine Science University, Nowshahr, Iran.

出版信息

Soft comput. 2023;27(6):3307-3326. doi: 10.1007/s00500-021-05839-6. Epub 2021 May 10.

DOI:10.1007/s00500-021-05839-6
PMID:33994846
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8107782/
Abstract

The COVID19 pandemic globally and significantly has affected the life and health of many communities. The early detection of infected patients is effective in fighting COVID19. Using radiology (X-Ray) images is, perhaps, the fastest way to diagnose the patients. Thereby, deep Convolutional Neural Networks (CNNs) can be considered as applicable tools to diagnose COVID19 positive cases. Due to the complicated architecture of a deep CNN, its real-time training and testing become a challenging problem. This paper proposes using the Extreme Learning Machine (ELM) instead of the last fully connected layer to address this deficiency. However, the parameters' stochastic tuning of ELM's supervised section causes the final model unreliability. Therefore, to cope with this problem and maintain network reliability, the sine-cosine algorithm was utilized to tune the ELM's parameters. The designed network is then benchmarked on the COVID-Xray-5k dataset, and the results are verified by a comparative study with canonical deep CNN, ELM optimized by cuckoo search, ELM optimized by genetic algorithm, and ELM optimized by whale optimization algorithm. The proposed approach outperforms comparative benchmarks with a final accuracy of 98.83% on the COVID-Xray-5k dataset, leading to a relative error reduction of 2.33% compared to a canonical deep CNN. Even more critical, the designed network's training time is only 0.9421 ms and the overall detection test time for 3100 images is 2.721 s.

摘要

新冠疫情在全球范围内对许多社区的生活和健康产生了重大影响。早期检测出感染患者对于抗击新冠疫情十分有效。使用放射学(X光)图像或许是诊断患者最快的方法。因此,深度卷积神经网络(CNN)可被视为诊断新冠阳性病例的适用工具。由于深度CNN架构复杂,其实时训练和测试成为一个具有挑战性的问题。本文提出使用极限学习机(ELM)替代最后一个全连接层来解决这一不足。然而,ELM监督部分参数的随机调整导致最终模型不可靠。因此,为解决此问题并保持网络可靠性,采用正弦余弦算法来调整ELM的参数。然后在COVID-Xray-5k数据集上对设计的网络进行基准测试,并通过与传统深度CNN、布谷鸟搜索优化的ELM、遗传算法优化的ELM和鲸鱼优化算法优化的ELM进行对比研究来验证结果。所提出的方法在COVID-Xray-5k数据集上以98.83%的最终准确率优于对比基准,与传统深度CNN相比相对误差降低了2.33%。更关键的是,设计网络的训练时间仅为0.9421毫秒,3100张图像的整体检测测试时间为2.721秒。

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