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探索 COVID-19 大流行期间用于个人健康的高效远程生物医学信号监测框架。

Exploring an Efficient Remote Biomedical Signal Monitoring Framework for Personal Health in the COVID-19 Pandemic.

机构信息

School of Computer Science and Technology, Hangzhou Dianzi University, Hangzhou 310014, China.

School of Information and Electronic Engineering, Zhejiang Gongshang University, Hangzhou 310018, China.

出版信息

Int J Environ Res Public Health. 2021 Aug 27;18(17):9037. doi: 10.3390/ijerph18179037.

DOI:10.3390/ijerph18179037
PMID:34501625
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8430740/
Abstract

Nowadays people are mostly focused on their work while ignoring their health which in turn is creating a drastic effect on their health in the long run. Remote health monitoring through telemedicine can help people discover potential health threats in time. In the COVID-19 pandemic, remote health monitoring can help obtain and analyze biomedical signals including human body temperature without direct body contact. This technique is of great significance to achieve safe and efficient health monitoring in the COVID-19 pandemic. Existing remote biomedical signal monitoring methods cannot effectively analyze the time series data. This paper designs a remote biomedical signal monitoring framework combining the Internet of Things (IoT), 5G communication and artificial intelligence techniques. In the constructed framework, IoT devices are used to collect biomedical signals at the perception layer. Subsequently, the biomedical signals are transmitted through the 5G network to the cloud server where the GRU-AE deep learning model is deployed. It is noteworthy that the proposed GRU-AE model can analyze multi-dimensional biomedical signals in time series. Finally, this paper conducts a 24-week monitoring experiment for 2000 subjects of different ages to obtain real data. Compared with the traditional biomedical signal monitoring method based on the AutoEncoder model, the GRU-AE model has better performance. The research has an important role in promoting the development of biomedical signal monitoring techniques, which can be effectively applied to some kinds of remote health monitoring scenario.

摘要

如今,人们大多专注于工作而忽视健康,这对他们的健康造成了长期的严重影响。通过远程医疗进行远程健康监测可以帮助人们及时发现潜在的健康威胁。在 COVID-19 大流行期间,远程健康监测可以帮助获取和分析包括人体温度在内的生物医学信号,而无需直接身体接触。这项技术对于在 COVID-19 大流行期间实现安全高效的健康监测具有重要意义。现有的远程生物医学信号监测方法无法有效分析时间序列数据。本文设计了一种结合物联网 (IoT)、5G 通信和人工智能技术的远程生物医学信号监测框架。在构建的框架中,物联网设备用于在感知层收集生物医学信号。随后,生物医学信号通过 5G 网络传输到部署了 GRU-AE 深度学习模型的云服务器。值得注意的是,所提出的 GRU-AE 模型可以及时分析时间序列中的多维生物医学信号。最后,本文对 2000 名不同年龄的受试者进行了为期 24 周的监测实验,以获得真实数据。与基于 AutoEncoder 模型的传统生物医学信号监测方法相比,GRU-AE 模型具有更好的性能。该研究在推动生物医学信号监测技术的发展方面具有重要作用,可有效应用于某些远程健康监测场景。

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