Abstract
Ballistocardiogram (BCG) is a graphical representation of the subtle oscillations in body movements caused by cardiovascular activity. Although BCGs cause less burden to the user, electrocardiograms (ECGs) are still commonly used in the clinical scene due to BCG sensors’ noise sensitivity. In this paper, a robust method for sleep time BCG measurement and a mathematical model for predicting sleep stages using BCG are described. The novel BCG measurement algorithm can be described in three steps: preprocessing, creation of heartbeat signal template, and template matching for heart rate variability detection. The effectiveness of this algorithm was validated with 99 datasets from 36 subjects, with photoplethysmography (PPG) to compute ground truth heart rate variability (HRV). On average, 86.9% of the inter-beat intervals were detected and the mean error was 8.5ms. This shows that our method successfully extracted beat-to-beat intervals from BCG during sleep, making its usability comparable to those of clinical ECGs. Consequently, compared to other conventional BCG systems, even more accurate sleep heart rate monitoring with a smaller burden to the patient is available. Moreover, the accuracy of the sleep stages mathematical model, validated with 100 datasets from 25 subjects, is 80%, which is higher than conventional five-stage sleep classification algorithms (max: 69%). Although, in this paper, we applied the mathematical model to heart rate interval features from BCG, theoretically, this sleep stage prediction algorithm can also be applied to ECG-extracted heart rate intervals.
Highlights
When the heart beats, blood inside the aortic vessels are pushed, causing expansions and contractions in response to the blood flow
The possibility of noninvasive and nonintrusive measurement is a big advantage of BCG systems as conventional techniques for measuring cardiac activities, which commonly require the subject’s body to be temporarily attached to electrodes, textiles, or other sensors
BCG research took off in 1877, when the performance of the circulatory system was shown to be interpretable from BCG signals
Summary
Blood inside the aortic vessels are pushed, causing expansions and contractions in response to the blood flow. This causes feeble, rhythmical involuntary movements in the body that can be detected by Ballistocardiograms (BCGs) [1]. There were two main problems in early BCG studies. Uniformity of the units are especially important in the field of data science and normalization is needed if the obtained data have different ranges. Studies in those days measured vibration using different devices and different nomenclatures
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