Influence of Sensor Position and Body Movements on Radar-Based Heart Rate Monitoring
Herzer L, Mücke A, Richer R, Albrecht NC, Heyder M, Jäger K, König V, Koelpin A, Rohleder N, Eskofier B (2022)
Publication Language: English
Publication Type: Conference contribution, Conference Contribution
Publication year: 2022
Original Authors: Liv Herzer, Annika Muecke, Robert Richer, Nils C. Albrecht, Markus Heyder, Katharina M. Jaeger, Veronika Koenig, Alexander Koelpin, Nicolas Rohleder, Bjoern M. Eskofier
Series: 2022 IEEE-EMBS International Conference on Biomedical and Health Informatics (BHI)
Event location: Ioannina
URI: https://www.mad.tf.fau.de/files/2022/11/herzer_muecke22_validation_mis.pdf
DOI: 10.1109/BHI56158.2022.9926775
Abstract
Cardiac parameters are important indicators for health assessment. Radar-based monitoring with microwave interferometric sensors (MIS) is a promising alternative to conventional measurement methods, as it enables completely contactless cardiac function diagnostics. In this study, we evaluated the effects of sensor positioning and movement on the accuracy of radar-based heart rate measurements with MIS. For this purpose, we recruited 29 participants which performed semi-standardized movements, a reading task, and a standardized laboratory stress test in a seated position. Furthermore, we compared three different sensor positions (dorsal, upper pectoral, and lower pectoral) to a gold standard 1-channel wearable ECG sensor node. The dorsal positioning achieved the best results with a mean error (ME) of 0.2±5.4 bpm and a mean absolute error (MAE) of 3.5±4.1 bpm for no movement and also turned out to be most robust against motion artifacts with an overall ME of 0.1±14.1 bpm (MAE: 9.5±10.4 bpm). No correlation was found between movement intensity and measurement error. Instead, movement type and direction were identified as primary impact factors. This study provides a valuable contribution towards the applicability of radar-based vital sign monitoring with MIS in real-world scenarios. However, further research is needed to sufficiently prevent and compensate for movement artifacts.
Authors with CRIS profile
Annika Mücke
Machine Learning and Data Analytics Lab
Robert Richer
Machine Learning and Data Analytics Lab
Nils Christian Albrecht
Sonderforschungsbereich 1483/1 Empathokinästhetische Sensorik – Sensortechniken und Datenanalyseverfahren zur empathokinästhetischen Modellbildung und Zustandsbestimmung (EmpkinS)
Markus Heyder
Sonderforschungsbereich 1483/1 Empathokinästhetische Sensorik – Sensortechniken und Datenanalyseverfahren zur empathokinästhetischen Modellbildung und Zustandsbestimmung (EmpkinS)
Katharina Jäger
Machine Learning and Data Analytics Lab
Veronika Ringgold
Machine Learning and Data Analytics Lab
Nicolas Rohleder
Lehrstuhl für Gesundheitspsychologie
Björn Eskofier
Machine Learning and Data Analytics Lab
Additional Organisation(s)
Related research project(s)
Kardiovaskuläres respiratorisches Mikrowelleninterferometer (SFB 1483 EmpkinS A04)
Empatho-Kinaesthetic Sensor Technology (SFB 1483 EmpkinS)
July 1, 2021 - June 30, 2025
Berührungslose Messung von Stress, seiner Determinanten und Konsequenzen (SFB 1483 EmpkinS D03)
Empatho-Kinaesthetic Sensor Technology (SFB 1483 EmpkinS)
July 1, 2021 - June 30, 2025
Empatho-Kinaesthetic Sensor Technology (SFB 1483 EmpkinS)
July 1, 2021 - June 30, 2025
Involved external institutions
Germany (DE)How to cite
APA:
Herzer, L., Mücke, A., Richer, R., Albrecht, N.C., Heyder, M., Jäger, K.,... Eskofier, B. (2022). Influence of Sensor Position and Body Movements on Radar-Based Heart Rate Monitoring. In IEEE (Eds.), Proceedings of the 2022 IEEE-EMBS International Conference on Biomedical and Health Informatics (BHI). Ioannina, GR.
MLA:
Herzer, Liv, et al. "Influence of Sensor Position and Body Movements on Radar-Based Heart Rate Monitoring." Proceedings of the 2022 IEEE-EMBS International Conference on Biomedical and Health Informatics (BHI), Ioannina Ed. IEEE, 2022.
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