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基于无人机和无线体域网的面向户外环境中老年人的高级急救系统。

An Advanced First Aid System Based on an Unmanned Aerial Vehicles and a Wireless Body Area Sensor Network for Elderly Persons in Outdoor Environments.

机构信息

Department of Medical Instrumentation Techniques Engineering, Electrical Engineering Technical College, Middle Technical University, Baghdad, Iraq.

College of Dentistry, University of Mosul, Mosul, Iraq.

出版信息

Sensors (Basel). 2019 Jul 4;19(13):2955. doi: 10.3390/s19132955.

DOI:10.3390/s19132955
PMID:31277484
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6651807/
Abstract

For elderly persons, a fall can cause serious injuries such as a hip fracture or head injury. Here, an advanced first aid system is proposed for monitoring elderly patients with heart conditions that puts them at risk of falling and for providing first aid supplies using an unmanned aerial vehicle. A hybridized fall detection algorithm (FDB-HRT) is proposed based on a combination of acceleration and a heart rate threshold. Five volunteers were invited to evaluate the performance of the heartbeat sensor relative to a benchmark device, and the extracted data was validated using statistical analysis. In addition, the accuracy of fall detections and the recorded locations of fall incidents were validated. The proposed FDB-HRT algorithm was 99.16% and 99.2% accurate with regard to heart rate measurement and fall detection, respectively. In addition, the geolocation error of patient fall incidents based on a GPS module was evaluated by mean absolute error analysis for 17 different locations in three cities in Iraq. Mean absolute error was 1.08 × 10° and 2.01 × 10° for latitude and longitude data relative to data from the GPS Benchmark system. In addition, the results revealed that in urban areas, the UAV succeeded in all missions and arrived at the patient's locations before the ambulance, with an average time savings of 105 s. Moreover, a time saving of 31.81% was achieved when using the UAV to transport a first aid kit to the patient compared to an ambulance. As a result, we can conclude that when compared to delivering first aid via ambulance, our design greatly reduces delivery time. The proposed advanced first aid system outperformed previous systems presented in the literature in terms of accuracy of heart rate measurement, fall detection, and information messages and UAV arrival time.

摘要

对于老年人来说,跌倒可能会导致严重伤害,如髋部骨折或头部受伤。在这里,提出了一种先进的急救系统,用于监测有心脏问题的老年患者,这些患者有跌倒的风险,并使用无人机提供急救用品。提出了一种基于加速度和心率阈值组合的混合跌倒检测算法(FDB-HRT)。邀请了五名志愿者评估心跳传感器相对于基准设备的性能,并使用统计分析验证提取的数据。此外,还验证了跌倒检测的准确性和跌倒事件的记录位置。所提出的 FDB-HRT 算法在心率测量和跌倒检测方面的准确率分别为 99.16%和 99.2%。此外,还通过在伊拉克三个城市的 17 个不同地点进行平均绝对误差分析,评估了基于 GPS 模块的患者跌倒事件的地理位置误差。相对于 GPS 基准系统的数据,纬度和经度数据的平均绝对误差分别为 1.08×10°和 2.01×10°。此外,结果表明,在城市地区,无人机成功完成了所有任务,并在救护车到达之前到达了患者的位置,平均节省了 105 秒。此外,与使用救护车相比,使用无人机向患者运送急救箱可节省 31.81%的时间。因此,我们可以得出结论,与通过救护车提供急救相比,我们的设计大大缩短了交付时间。与文献中提出的先前系统相比,所提出的先进急救系统在心率测量、跌倒检测、信息消息和无人机到达时间方面的准确性方面表现出色。

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