Soli-enabled noncontact heart rate detection for sleep and meditation tracking

Heart rate (HR) is a crucial physiological signal that can be used to monitor health and fitness. Traditional methods for measuring HR require wearable devices, which can be inconvenient or uncomfortable, especially during sleep and meditation. Noncontact HR detection methods employing microwave rad...

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Bibliographic Details
Published in:Scientific reports 2023-10, Vol.13 (1), p.18008-18008, Article 18008
Main Authors: Xu, Luzhou, Lien, Jaime, Li, Haiguang, Gillian, Nicholas, Nongpiur, Rajeev, Li, Jihan, Zhang, Qian, Cui, Jian, Jorgensen, David, Bernstein, Adam, Bedal, Lauren, Hayashi, Eiji, Yamanaka, Jin, Lee, Alex, Wang, Jian, Shin, D, Poupyrev, Ivan, Thormundsson, Trausti, Pathak, Anupam, Patel, Shwetak
Format: Article
Language:English
Subjects:
639/166/985
639/166/987
Datasets
Heart rate
Humanities and Social Sciences
Meditation
Microwave radar
multidisciplinary
Radar
Science
Science (multidisciplinary)
Signal processing
Sleep
Wearable computers
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Summary:Heart rate (HR) is a crucial physiological signal that can be used to monitor health and fitness. Traditional methods for measuring HR require wearable devices, which can be inconvenient or uncomfortable, especially during sleep and meditation. Noncontact HR detection methods employing microwave radar can be a promising alternative. However, the existing approaches in the literature usually use high-gain antennas and require the sensor to face the user’s chest or back, making them difficult to integrate into a portable device and unsuitable for sleep and meditation tracking applications. This study presents a novel approach for noncontact HR detection using a miniaturized Soli radar chip embedded in a portable device (Google Nest Hub). The chip has a 6.5 mm × 5 mm × 0.9 mm dimension and can be easily integrated into various devices. The proposed approach utilizes advanced signal processing and machine learning techniques to extract HRs from radar signals. The approach is validated on a sleep dataset (62 users, 498 h) and a meditation dataset (114 users, 1131 min). The approach achieves a mean absolute error (MAE) of 1.69 bpm and a mean absolute percentage error (MAPE) of 2.67 % on the sleep dataset. On the meditation dataset, the approach achieves an MAE of 1.05 bpm and a MAPE of 1.56 % . The recall rates for the two datasets are 88.53 % and 98.16 % , respectively. This study represents the first application of the noncontact HR detection technology to sleep and meditation tracking, offering a promising alternative to wearable devices for HR monitoring during sleep and meditation.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-023-44714-2