ABSTRACT
Covid Security System is a non-contact sanitizer dispenser, that also monitors vital parameters such as temperature, heart rate, and spo2 sensors based on Internet of Things (IOT) data collection and processing. This device is vital in workplaces like hospitals, colleges, and many more. The system that has the capability to record human body temperature based on contactless mechanism efficiently with pandemic situation has looked up to usage of infrared thermometers. In this paper via our research we realize the human body temperature fast non-contact by utilizing infrared thermometer (MLX90614) along with a pulse oximeter using a pulse sensor (MAX30100) to measure the heart rate in real-time. Parameter like the oxygen level of the user is also rendered and stored on our designed IOT processing framework which can provide alerts both online or offline based on previous maintained records. In this research we have recorded parameters of the sample space comprising of 500 users. The main aspect of the research is the cost affectability where is the system can be easily interfaced with any existing framework of workplaces.
ABSTRACT
Today, the trends are the robotics field since it is used in too many environments that are very important in human life. Covid 19 disease is now the deadliest disease in the world, and most studies are being conducted to find solutions and avoid contracting it. The proposed system senses the presence according to a specific injury to warn of it and transfer it to the specialist doctor. This system is designed to work in service departments such as universities, institutes, and all state departments serving citizens. This system consists of two parts: the first is fixed and placed on the desk and the other is mobile within a special robot that moves to perform the required task. This system was tested at the University of Basrah within the college of engineering, department of electrical Engineering, on teaching staff, students, and staff during the period of final academic exams. The presence of such a device is considered a warning according to a specific condition and isn't a treatment for it, as the treatment is prescribed by the specialist doctor. It is found that the average number of infected cases is about 3% of the total number of students and the teaching staff and the working staff. The results were documented in special tables that go to the dean of the college with the attendance tables to know the daily health status of the students. [ FROM AUTHOR]
ABSTRACT
With the recent Covid-19 pandemic put break, people are becoming more conscious on checking their SpO2 (Percentage of Oxygen in our blood) and heart rate levels. The pulse oximeter is a widely used clinical instrument for performing effortless testing via a non-intrusive method. The proposed system is a smart device that has been used to monitor the health vitals and monitoring these vitals can help us to track the SpO2 and heart rate. The proposed device comprises of simple components such as a MAX30100 pulse oximeter sensor and an ESP8266 Node MCU. This device can be connected to Blynk App to monitor the regularly updated data through the web by connecting to a Wi-Fi. In addition to this, the SpO2 percentage and heart rate can also be observed on the OLED Display. The proposed system can assist in detecting the health abnormalities like pneumonia, asthma, and many other respiratory diseases. © 2022 IEEE.
ABSTRACT
According to ways-to-die website, over 150,000 people die every day. And the most common cause of death, i.e., about 20% of all deaths, is heart diseases. So, the most crucial contribution from our side to lower this percentage can be to monitor the cardiac values as much as possible. There are conventional methods to measure patients' health and condition, but they are laborious;have possibilities of errors;and nocturnal monitoring has as well been very difficult. Moreover, since 2019, COVID19 has caused more than five million deaths all around the world, as stated by WHO. And it made the physical presence of doctors and caretakers almost impossible. So, we have designed an up-to-date IoT-based project that continuously monitors the patient's body temperature, heart-rate and oxygen saturation level;keep the data readings in display before the patient and in the screen of the doctor's mobile;and it also provides a non-touching handsanitizing system. The proposed design integrates NodeMCU, DS18B20 Temperature sensor, Max30100 Pulse-oximeter, and other required materials in a small box. The readings are as accurate as the conventional medical equipments while it just takes less than a minute of time to perform the whole procedure. The developed project has outperformed the conventional method by providing a safer, less complex, cost effective and faster service. © 2022 IEEE.
ABSTRACT
Ever since the COVID-19 pandemic, the necessity of new,innovative medical devices to analyse and monitor the situation has become profound. With this in mind, we have developed an IOT based portable and cost-efficient heart rate and SpO2/level sensor device with efficient performance. The proposed system is equipped with an onboard OLED with simple internet connectivity, which publishes data on the OLED and to a HTML webpage. The salient features include its portability, user compatibility and is unique in its way of transmitting collected data online, making it achieve better results than the current available solutions in various ways. The system has on board a MAX30100 sensor(Pulse Oximeter sensor) and along with the IOT based microcontroller(WeMos D1 mini) enables the facility to monitor the real time health data of patients in real-time through a HTML page.
ABSTRACT
The present covid-19 pandemic necessitates the need for a cost effective and efficient remote health monitoring mechanisms for the collection, transmission, evaluation, and communication of patient health data from electronic devices since many find it difficult to go for regular medical checkup due to safety concerns. Therefore, we require a remote health monitoring system that can monitor different body parameters and transmit it to a health care provider in a remote location. This paper describes the design and development of a remote health monitoring system capable of measuring ECG, Heart rate and SpO2 using AD8232, MAX30100 or MAX30102 and transfer this information to physicians using IoT. The ESP32 module is used to establish the IoT connectivity and share the vital information to medical practitioners for real-time analysis through a smartphone or Tab. In the present work, Blynk IoT cloud platform is used to communicate with hardware and software. The size of the designed PCB board is less than 60mm x 60 mm, therefore the size and weight of the device are very small and able to attach on the patient's cloth or in the body with the help of a Velcro belt. This helps the patient to easily carry the device without any discomfort. © 2021 IEEE.
ABSTRACT
In the present COVID-19 situation, remote monitoring of a patient is preferred over contact monitoring, here Using ZigBee we can achieve it. Covid patient’s oxygen levels are deteriorating suddenly so need to setup an alarming system for low-blood oxygen levels (hypoxemia). By monitoring the heartbeat of patients with certain pre-medical conditions, we can save them from sudden heart attacks. This paper describes the working of a wireless-based health monitoring system that monitors parameters like SpO2 (oxygen saturation in the blood), heart rate of a human with the help of Max30100 integrated pulse oximetry and heart-rate monitor sensor. Most of the systems that are used nowadays work in offline mode (storing data and sending it later), but this system is designed for real-time monitoring of a patient. A lot of conventional systems use wired communication technology but here the data is transmitted wirelessly from one system to another through two Xbees (Co-ordinator Xbee and Router Xbee). Abnormalities in the patient can be monitored and indications can be sent to medical officials/doctors. The implementation can be achieved by using an Arduino Uno Microcontroller and ZigBee. © 2022, The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd.