基于磁共振无线供电的智能健康系统研究

发布时间：2018-05-11 19:14

  本文选题：磁耦合无线充电 + 智能健康　； 参考：《电子科技大学》2017年硕士论文

【摘要】：随着社会经济的发展、人类科学技术的进步,人们对医疗卫生条件的要求越来越高,尤其期望医疗设备具有良好的安全性,高效性、便利性和舒适性。传统的人体健康检测系统只注重将人体数据采集到医疗设备并显示,缺少数据共享交互、云端存储等重要的功能,同时检测器件过于庞大,使用费用十分昂贵,再加上传感器的传统供电方式也比较单一,使用起来非常不方便,阻碍了医疗卫生改善的脚步。因此本文提出一种基于磁共振无线供电的智能健康系统,即提出一种让健康检测模块以无线技术方式实现自供电,然后通过自主开发的无线数据接收功能的中继设备,接收人体健康监控设备发射的体温、脉搏等数据,并发射到服务器网关,以提供网络终端设备对数据的检测和共享的物联网系统。该系统的目标就是解决人们要求对健康时刻关注的问题,实时性、有效性地对每个用户的健康进行检测。方便、快捷地将被检测者生理数据上传到服务器,以供医生或用户自身查看最新且较全面的身体状况数据。同时,采用目前最新的磁耦合无线充电技术,提升了用户的体验,使得生理数据检测传感器供电方式无绳化,让用户在使用中安全便捷。本文在提出此系统的基础下,设计了一个智能健康系统原型机,其中原型机系统设计中采用了磁耦合无线供电技术,应用了 ZigBee无线传感器网络、单片机、传感器等手段,以MSP430单片机作为生理数据终端采集电路的主控芯片,通过ZigBee无线传感器网络实现系统的无线通信。在原型机系统稳定可靠运行的基础下,为了将此原型机进一步小型化,本文又设计一款以“双无线”体温计为例的小型化的产品。该产品在删去部分原型机的功能后,使得体积小巧,能够让用户随身携带,通过磁耦合方式激活电源后,将用户的体温数据实时无线发出。基于磁共振无线供电的智能健康系统以数据的无线传输和能量的无线供给为两大特色,拓展了传感器的供电方式,加大了检测对象的数量,同时数据共享交互、云端存储等功能也能及时方便地将人体健康状况反馈给用户,从而在一定程度上提高了现阶段的医疗监测水平。
[Abstract]:With the development of social economy and the progress of human science and technology, people demand more and more medical and health conditions, especially the medical equipment has good security, high efficiency, convenience and comfort. The traditional human health detection system only pays attention to collecting and displaying human body data into medical equipment, lacks important functions such as data sharing interaction, cloud storage, and so on. At the same time, the detection devices are too large and expensive to use. In addition, the traditional power supply of sensors is also relatively simple, very inconvenient to use, hindering the pace of medical and health improvement. Therefore, this paper presents an intelligent health system based on magnetic resonance wireless power supply, that is, a kind of relay equipment, which enables the health detection module to realize self-power supply by wireless technology, and then through the self-developed wireless data receiving function. Receiving the temperature, pulse and other data from the human health monitoring equipment, then shooting to the server gateway to provide the Internet of things system for the detection and sharing of the data by the network terminal equipment. The goal of the system is to solve the problem that people need to pay attention to at all times. It is convenient and fast to upload the physical data to the server for doctors or users to view the latest and more comprehensive body condition data. At the same time, the use of the latest magnetic coupling wireless charging technology, improve the user experience, make physiological data detection sensor power supply mode cordless, so that users in the use of safe and convenient. Based on this system, an intelligent health system prototype is designed in this paper, in which the magnetic coupling wireless power supply technology is used in the prototype system design, and the ZigBee wireless sensor network, single chip microcomputer, sensor and other means are used. The MSP430 microcontroller is used as the main control chip of the collection circuit of physiological data terminal, and the wireless communication of the system is realized through the ZigBee wireless sensor network. On the basis of stable and reliable operation of the prototype system, in order to further miniaturize the prototype, a miniaturized product is designed, which takes "double wireless" thermometers as an example. After deleting some of the function of the prototype machine, the product makes it small and can be carried by the user. After activating the power supply by magnetic coupling, the temperature data of the user can be sent out wirelessly in real time. The intelligent health system based on magnetic resonance wireless power supply is characterized by wireless transmission of data and wireless supply of energy, which expands the power supply mode of sensors, increases the number of detection objects, and shares data with each other. Cloud storage and other functions can also timely and conveniently feed back the health status of the human body to users, thus improving the level of medical monitoring at this stage to a certain extent.
【学位授予单位】：电子科技大学
【学位级别】：硕士
【学位授予年份】：2017
【分类号】：TP212.9;R318

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