The development of increasingly modern technology makes it possible to create a more advanced tool. The health sector as one of the important components of life also does not escape the support of technology. One of its implementations is an android-based heart rate and oxygen level monitoring system (oximeter). Heart rate monitoring can be done by everyone by utilizing existing technological developments. Measurements are made using only the fingers of the hand as input. The purpose of this study was to determine the design of a research tool for a heart rate monitoring system and blood oxygen levels (oximeter) based on android. This measuring instrument uses a Max30100 sensor which is attached to one person's fingertip to detect a heart rate signal, then the data generated by the sensor is received by Arduino, after that it is forwarded to Bluetooth and displayed on the Android application, then it will be processed into beats per minute (BPM) and blood oxygen levels (SPO2) so that you can find out the results of heart rate and oxygen levels displayed on Android. Based on the results obtained in heart rate monitoring, it can work well so that it can be seen the results of measurements using a device made with a person in normal conditions the heart rate beats between 60 to 75 beats per minute  (BPM) and oxygen levels (SpO2) which can beat between 95 to 100, while using pulse oximetry  results in normal body conditions the heart rate beats between 60 to 75 beats per minute  (bpm) and oxygen levels (SpO2) which can be between 95 and 100 oxygen levels (SpO2).

Oximeter; Bluetooth; Sensor Max30100; Android

L. I. Keshk, S. A. A. Qalawa and N. A. Ibrahim, “Effectiveness of an educational program regarding nursing process on acquiring advanced skills among internship nursing students,” Int J Nurs, vol. 5, no. 2, pp. 32-44, 2018.

D. Di Mitri, M. Scheffel, H. Drachsler, D. Börner, S. Ternier and M. Specht, “Learning pulse: A machine learning approach for predicting performance in self-regulated learning using multimodal data,” In Proceedings of the seventh international learning analytics & knowledge conference, pp. 188-197, 2017.

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), Dhaka, Bangladesh, 2015, pp. 1-6, doi: 10.1109/NSysS.2015.7043525.

M. P. Turakhia et al., ”Rationale and design of a large-scale, app-based study to identify cardiac arrhythmias using a smartwatch: The Apple Heart Study,” American heart journal, vol. 207, pp. 66-75, 2019 .

Y. Khan, A. E. Ostfeld, C. M. Lochner, A. Pierre and A. C. Arias, “Monitoring of vital signs with flexible and wearable medical devices,” Advanced materials, vol. 28, no. 22, pp. 4373-4395, 2016.

P. Gupta, D. Agrawal, J. Chhabra and P. K. Dhir, "IoT based smart healthcare kit," 2016 International Conference on Computational Techniques in Information and Communication Technologies (ICCTICT), New Delhi, India, 2016, pp. 237-242, doi: 10.1109/ICCTICT.2016.7514585.

L. C. Banuag and J. K. G. Salva, "Development of a Patient Monitoring System for Hospital Wards Employing Zigbee Technology and CAN Protocol," 2019 2nd World Symposium on Communication Engineering (WSCE), Nagoya, Japan, 2019, pp. 112-116, doi: 10.1109/WSCE49000.2019.9040975..

V. A., S. S., S. N. and S. Ambesange, "Multi-Disease Prediction with Artificial Intelligence from Core Health Parameters Measured through Non-invasive Technique," 2020 4th International Conference on Intelligent Computing and Control Systems (ICICCS), Madurai, India, 2020, pp. 1252-1258, doi: 10.1109/ICICCS48265.2020.9121170..

Iswanto and P. Megantoro, "Detection of Hypoxic Symptoms System Based on Oxygen Saturation and Heart Rate Using Arduino Based Fuzzy Method," 2020 2nd International Conference on Industrial Electrical and Electronics (ICIEE), Lombok, Indonesia, 2020, pp. 107-111, doi: 10.1109/ICIEE49813.2020.9276818.

S. K. Longmore, G. Y. Lui, G. Naik, P. P. Breen, B. Jalaludin and G. D. Gargiulo, “A comparison of reflective photoplethysmography for detection of heart rate, blood oxygen saturation, and respiration rate at various anatomical locations. Sensors, vol. 19, no. 8, p. 1874, 2019.

This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.