A Self-Powered Wearable Device using the Photovoltaic Effect for Human Heath Monitoring

2021 IEEE 20th International Conference on Micro and Nanotechnology for Power Generation and Energy Conversion Applications (PowerMEMS) Pub Date : 2021-12-06 DOI:10.1109/PowerMEMS54003.2021.9658359

Vishal Gyanchandani, S. N. Masabi, Hailing Fu

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引用次数: 1

Abstract

Wearable monitors have revolutionized the healthcare industry with help of non-invasive measurement technologies. However, the adoption of these vital monitors faces challenges such as high-power consumption and limited battery lifetime. In this paper, to overcome these challenges, a self-powered wearable monitoring system is designed, integrated, and experimentally validated. The system includes a photovoltaic panel (PV), a DC-DC converter, supercapacitors, a pulse sensor, an accelerometer, a microcontroller unit and a Bluetooth module to extract critical physiological parameters, including heart rate, oxygen saturation, activity of daily living and deliver wireless data access to a mobile device. A theoretical model of the energy balance model was established to realize the balance between the energy harvesting capability and sensing power consumption. In an experimental study, a 50 F supercapacitor stored 430 J in 4 hours (29.9 mW) using a PV energy harvester at 500 W/m2, which allows the sensor system (power consumption 5mW) to run sustainably for 24 h.

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一种利用光伏效应的自供电可穿戴设备用于人体健康监测

可穿戴式显示器在非侵入式测量技术的帮助下彻底改变了医疗保健行业。然而，采用这些重要的监视器面临着诸如高功耗和有限的电池寿命等挑战。为了克服这些挑战，本文设计、集成并实验验证了一种自供电可穿戴监测系统。该系统包括一个光伏板(PV)、一个DC-DC转换器、超级电容器、一个脉冲传感器、一个加速度计、一个微控制器单元和一个蓝牙模块，用于提取关键的生理参数，包括心率、氧饱和度、日常生活活动，并向移动设备提供无线数据访问。建立了能量平衡模型的理论模型，实现了能量收集能力与传感功耗之间的平衡。在一项实验研究中，一个50 F的超级电容器使用500 W/m2的光伏能量收集器在4小时内存储430 J (29.9 mW)，这使得传感器系统(功耗5mW)可持续运行24小时。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 IEEE 20th International Conference on Micro and Nanotechnology for Power Generation and Energy Conversion Applications (PowerMEMS)

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