Ubiquitous Electronic Health System - Rancang Bangun Smart Mouse dan Smart Watch Pengukur Denyut Jantung dan Suhu Tubuh
Abstract
The purpose of this research is to design a Ubiquitous Electronic Health System to monitor health during activities. The Ubiquitous Electronic Health System is a health monitoring system and facilitator of human health support devices that are applied to devices commonly used in everyday life such as mirrors, chairs, computer mice, watches, mobile phones, and others by utilizing the Photoplethysmograph method. The equipment developed in this study consisted of a computer mouse and a watch that was added with a photodiode, infrared, and a DS18b20 sensor with functionality as a heart rate detector and body temperature measurement. into the body but the measurement or screening action is carried out with the help of sensors attached to the skin, measurements are carried out in real-time when the equipment is used daily, the measurement results can be seen on the mobile phone screen and desktop applications, the data obtained from the measurement results can then be sent to the server to be stored as a user's medical record which can be used by the user to carry out further examinations to the doctor. The parameters that are the points in this study are the number of heart beats per minute and the measurement of body temperature, these two parameters are tested by comparing the results of tests carried out by tools designed with oximeters and thermometers. The test results from the Ubiquitous Electronic Health System tool provide an accuracy of up to 98% for measuring heart rate and 85% for measuring body temperature. Design and schematic have been shown in this study.
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References
[2] Nusi, Danial T., Danes, Vennetia R., Moningka, Maya E.W. Perbandingan Suhu Tubuh berdasarkan Pengukuran Menggunakan Termometer Air Raksa dan Termometer Digital pada Penderita Demam di Rumah Sakit Umum Kandou Manado, jurnal Universitas Sam Ratulangi, 2013.
[3] WHO, World Health Organization, 2021 [Online]. https://www.who.int/health-topics/cardiovascular-diseases.
[4] Setyaji, Diyan Yunanto; Prabandari, Yayi Suryo; dan Gunawan, I Made Alit.”Aktivitas fisik dengan penyakut jantung koroner di Indonesia”, Jurnal Gizi Klinik Indonesia, 2018, Vol 14 No 3.
[5] O. Geman, I. Chiuchisan, I. Ungurean, M. Hagan and M. Arif, "Ubiquitous Healthcare System Based on the Sensors Network and Android Internet of Things Gateway," 2018 IEEE SmartWorld, Ubiquitous Intelligence & Computing, Advanced & Trusted Computing, Scalable Computing & Communications, Cloud & Big Data Computing, Internet of People and Smart City Innovation (SmartWorld/SCALCOM/UIC/ATC/CBDCom/IOP/SCI), 2018, pp. 1390-1395.
[6] S. Kim, S. Yeom, O. Kwon, D. Shin and D. Shin, "Ubiquitous Healthcare System for Analysis of Chronic Patients’ Biological and Lifelog Data," in IEEE Access, vol. 6, pp. 8909-8915, 2018.
[7] Lynn S. Bickley, Wolters Kluwer Health|Lippincott Williams & Wilkins , Gates’Guide to Physical Examination and History Talking, Eleventh Edition, [120], China, 2013.
[8] D. Biswas, N. Simões-Capela, C. Van Hoof and N. Van Helleputte, "Heart Rate Estimation From Wrist-Worn Photoplethysmography: A Review," in IEEE Sensors Journal, vol. 19, no. 16, pp. 6560-6570, 15 Aug.15, 2019.
[9] N. Saquib, M. T. I. Papon, I. Ahmad and A. Rahman, "Measurement of heart rate using photoplethysmography," 2015 International Conference on Networking Systems and Security (NSysS), 2015, pp. 1-6.
[10] H. Mansor, M. H. A. Shukor, S. S. Meskam, N. Q. A. M. Rusli and N. S. Zamery, "Body temperature measurement for remote health monitoring system," 2013 IEEE International Conference on Smart Instrumentation, Measurement and Applications (ICSIMA), 2013, pp. 1-5.
[11] Trobec, Roman, and Aleksandra Rashkovska, and Viktor Avbelj Two Proximal Skin Electrodes – A Respiration Body Sensor, Sensors,Jozef Stefan Institute, Slovenia, 2012.
[12] H. Lee, H. Chung, H. Ko and J. Lee, "Wearable Multichannel Photoplethysmography Framework for Heart Rate Monitoring During Intensive Exercise," in IEEE Sensors Journal, vol. 18, no. 7, pp. 2983-2993, 1 April1, 2018.
[13] AMA, American Medical Association, 2021. [Online]. http://healthcaresciencesocw.wayne.edu.
[14] Agro, Diego & Canicattì, R & Tomasino, Alessandro & Giordano, A & Adamo, Gabriele & Parisi, Antonino & Pernice, Riccardo & Stivala, Salvatore & Giaconia, Costantino & Busacca, Alessandro & Ferla, Giuseppe. (2014). PPG Embedded System for Blood Pressure Monitoring.
[15] Wahyu Wohingati, Galuh., Subari, Arkhan. “Alat Pengukur Detak Jantung Menggunakan Pulsesensor Berbasis Arduino UNO R3 yang diintegrasikan dengan Bluetooth”, GEMA TEKNOLOGIGEMA TEKNOLOGI Vol. 17 No. 2 Periode Oktober 2012 - April 2013.
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