Abstract
Due to the spread of the new coronavirus, medical care has become very important in many countries these days. IoT-based health monitoring systems are thus the ideal answer for such an epidemic from this perspective. The Internet of Things (IoT) is a recent internet revolution and a burgeoning field of study, particularly in the field of medicine. With the growing use of wearable sensors and smartphones, this remote healthcare monitoring has evolved at such a pace. IoT health monitoring helps doctors correctly diagnose health conditions, not only to prevent the spread of diseases, even when they are out of reach. In this paper, we present a portable physiological monitoring system that can continuously monitor heart rate, temperature, and other basic parameters of a patient's room. Designed a continuous monitoring and control device that uses remote communication based on Wi-Fi module to display patient status and store patient information on the server. A remote health monitoring system built with the Internet of Things is intended to give authorized users access to the data using any IoT platform. Based on the received data, clinicians can remotely manage your health. Diagnose the disease. Oxygen impairment can occur at different stages of Covid-19 and is not limited to critically ill patients. In fact, a phenomenon called "happy hypoxia" has been observed clinically in patients with COVID-19 who have very low oxygen levels but otherwise appear to be fine. A pulse oximeter, usually a small device that you slip on your fingertip or rub against your earlobe, uses refraction of infrared light to measure the amount of oxygen bound to red blood cells. The proposed system monitors SPO2 levels to track Covid-19 symptoms.
Index Terms— IoT, Wi-Fi, Oxygen, SPO2, ear-lobe, hypoxia.
References
[1]. S.H. Almotiri, M. A. Khan, and M. A. Alghamdi. Mobile health (m- health) system in the context of iot. In 2016 IEEE 4th International Conference on Future Internet of Things and Cloud Workshops (FiCloudW), pages 39–42, Aug 2016.
[2]. Gulraiz J. Joyia, Rao M. Liaqat, Aftab Farooq, and Saad Rehman, Internet of Medical Things (IOMT): Applications, Benefits and Future Challenges in Healthcare Domain, Journal of Communications Vol. 12, No. 4, April 2017.
[3]. Shubham Banka, Isha Madan and S.S. Saranya, Smart Healthcare Monitoring using IoT. International Journal of Applied Engineering Research ISSN 0973-4562 Volume 13, Number 15, pp. 11984-11989, 2018.
[4]. K. Perumal, M. Manohar, A Survey on Internet of Things: Case Studies, Applications, and Future Directions, In Internet of Things: Novel Advances and Envisioned Applications, Springer International Publishing, (2017) 281- 297.
[5]. S.M. Riazulislam, Daehankwak, M.H.K.M.H., Kwak, K.S.: The Internet of Things for Health Care: A Comprehensive Survey. In: IEEE Access (2015).
[6]. P. Rizwan, K. Suresh. Design and development of low investment smart hospital using Internet of things through innovative approaches, Biomedical Research. 28(11) (2017).
[7]. K.R. Darshan and K.R. Anandakumar, “A comprehensive review on usage of internet of things (IoT) in healthcare system,” in Proc. International Conference on Emerging Research in Electronics, Computer Science and Technology, 2015.
[8]. Internet of Things (IoT): Number of Connected Devices Worldwide From 2012 to 2020 (in billions). [Online].Available:https://www.statista.com/statistics/471264/iotnumberof- connected- devices-worldwide/
[9]. P. Chavan, P. More, N. Thorat, S. Yewale, and P. Dhade, “ECG - Remote patient monitoring using cloud computing,” Imperial Journal of Interdisciplinary Research, vol. 2, no. 2, 2016.
[10]. Ruhani Ab. Rahman, NurShima Abdul Aziz, MurizahKassim, Mat IkramYusof, IoT- based Personal Health Care Monitoring Device for Diabetic Patients ,978-1-5090- 4752-9/17/2017 IEEE.
[11]. Valsalan P, Surendran P, Implementation of an Emergency Indicating Line Follower and Obstacle Avoiding Robot, 16th International Multi-Conference on Systems, Signals and Devices, SSD 2019.
[12]. Valsalan P, Shibi O, CMOS-DRPTL Adder Topologies, Proceedings of the 2018 International Conference on Current Trends towards Converging Technologies, ICCTCT 2018.
[13]. Valsalan P, Manimegalai P, Intend of power-delay optimized Kogge-Stone based Carry Select Adder, ARPN Journal of Engineering and Applied Sciences, 2018.
[14]. Valsalan P, Surendran P, Iot based breath sensor for mycobacterium tuberculosis, Journal of Advanced Research in Dynamical and Control Systems, 2018.
[15]. Firas Hasan Bazzari. "Available Pharmacological Options and Symptomatic Treatments of Multiple Sclerosis." Systematic Reviews in Pharmacy 9.1 (2018), 17-21. Print. doi:10.5530/srp.2018.1.4
[16]. Valsalan P, Manimegalai P, Analysis of area delay optimization of improved sparse channel adder, Pakistan Journal of Biotechnology, 2017.
[17]. Valsalan P, Sankaranarayanan K, Design of adder circuit with fault tolerant technique for power minimization, International Journal of Applied Engineering Research, 2014.
[18]. Rajendran T et al. “Recent Innovations in Soft Computing Applications”, Current Signal Transduction Therapy. Vol. 14, No. 2, pp. 129 – 130, 2019.