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COVID安全:一种基于物联网的系统,用于大流行后生活中的自动健康监测与监视。

COVID-SAFE: An IoT-Based System for Automated Health Monitoring and Surveillance in Post-Pandemic Life.

作者信息

Vedaei Seyed Shahim, Fotovvat Amir, Mohebbian Mohammad Reza, Rahman Gazi M E, Wahid Khan A, Babyn Paul, Marateb Hamid Reza, Mansourian Marjan, Sami Ramin

机构信息

Department of Electrical and Computer EngineeringUniversity of Saskatchewan Saskatoon SK S7N 5A9 Canada.

College of MedicineSaskatchewan Health Authority Saskatoon SK S7K 0M7 Canada.

出版信息

IEEE Access. 2020 Oct 12;8:188538-188551. doi: 10.1109/ACCESS.2020.3030194. eCollection 2020.

DOI:10.1109/ACCESS.2020.3030194
PMID:34812362
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8545279/
Abstract

In the early months of the COVID-19 pandemic with no designated cure or vaccine, the only way to break the infection chain is self-isolation and maintaining the physical distancing. In this article, we present a potential application of the Internet of Things (IoT) in healthcare and physical distance monitoring for pandemic situations. The proposed framework consists of three parts: a lightweight and low-cost IoT node, a smartphone application (app), and fog-based Machine Learning (ML) tools for data analysis and diagnosis. The IoT node tracks health parameters, including body temperature, cough rate, respiratory rate, and blood oxygen saturation, then updates the smartphone app to display the user health conditions. The app notifies the user to maintain a physical distance of 2 m (or 6 ft), which is a key factor in controlling virus spread. In addition, a Fuzzy Mamdani system (running at the fog server) considers the environmental risk and user health conditions to predict the risk of spreading infection in real time. The environmental risk conveys from the virtual zone concept and provides updated information for different places. Two scenarios are considered for the communication between the IoT node and fog server, 4G/5G/WiFi, or LoRa, which can be selected based on environmental constraints. The required energy usage and bandwidth (BW) are compared for various event scenarios. The COVID-SAFE framework can assist in minimizing the coronavirus exposure risk.

摘要

在新冠疫情最初的几个月里,由于没有指定的治疗方法或疫苗,打破感染链的唯一方法就是自我隔离并保持社交距离。在本文中,我们介绍了物联网(IoT)在大流行情况下的医疗保健和社交距离监测中的潜在应用。所提出的框架由三部分组成:一个轻量级、低成本的物联网节点、一个智能手机应用程序(应用)以及用于数据分析和诊断的基于雾计算的机器学习(ML)工具。物联网节点跟踪健康参数,包括体温、咳嗽频率、呼吸频率和血氧饱和度,然后更新智能手机应用程序以显示用户的健康状况。该应用程序会通知用户保持2米(或6英尺)的社交距离,这是控制病毒传播的关键因素。此外,一个模糊Mamdani系统(在雾服务器上运行)会考虑环境风险和用户健康状况,以实时预测感染传播的风险。环境风险源自虚拟区域概念,并为不同地点提供更新信息。物联网节点与雾服务器之间的通信考虑了两种场景,即4G/5G/WiFi或LoRa,可根据环境限制进行选择。针对各种事件场景比较了所需的能源使用和带宽(BW)。COVID-SAFE框架有助于将冠状病毒暴露风险降至最低。

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