Distinguishing Sleep from Wake with a Radar Sensor: a Contact-free Real-time Sleep Monitor

Overview

Journal Sleep

Publisher Oxford University Press

Specialty Psychiatry

Date 2021 Mar 11

PMID 33705555

Citations 6

Authors

Hanne Siri Amdahl Heglum

Havard Kallestad

Daniel Vethe

Knut Langsrud

Trond Sand

Morten Engstrom

Affiliations

Soon will be listed here.

Abstract

This work aimed to evaluate whether a radar sensor can distinguish sleep from wakefulness in real time. The sensor detects body movements without direct physical contact with the subject and can be embedded in the roof of a hospital room for completely unobtrusive monitoring. We conducted simultaneous recordings with polysomnography, actigraphy, and radar on two groups: healthy young adults (n = 12, four nights per participant) and patients referred to a sleep examination (n = 28, one night per participant). We developed models for sleep/wake classification based on principles commonly used by actigraphy, including real-time models, and tested them on both datasets. We estimated a set of commonly reported sleep parameters from these data, including total-sleep-time, sleep-onset-latency, sleep-efficiency, and wake-after-sleep-onset, and evaluated the inter-method reliability of these estimates. Classification results were on-par with, or exceeding, those often seen for actigraphy. For real-time models in healthy young adults, accuracies were above 92%, sensitivities above 95%, specificities above 83%, and all Cohen's kappa values were above 0.81 compared to polysomnography. For patients referred to a sleep examination, accuracies were above 81%, sensitivities about 89%, specificities above 53%, and Cohen's kappa values above 0.44. Sleep variable estimates showed no significant intermethod bias, but the limits of agreement were quite wide for the group of patients referred to a sleep examination. Our results indicate that the radar has the potential to offer the benefits of contact-free real-time monitoring of sleep, both for in-patients and for ambulatory home monitoring.

Citing Articles

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PMID: 39541279 PMC: 11563468. DOI: 10.1371/journal.pone.0313286.

Respiration-triggered olfactory stimulation reduces obstructive sleep apnea severity: A prospective pilot study.

Perl O, Kemer L, Green A, Arish N, Corcos Y, Arzi A J Sleep Res. 2024; 33(6):e14236.

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Evaluation of the Accuracy of Contactless Consumer Sleep-Tracking Devices Application in Human Experiment: A Systematic Review and Meta-Analysis.

Zhai H, Yan Y, He S, Zhao P, Zhang B Sensors (Basel). 2023; 23(10).

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Contact-free radar recordings of body movement can reflect ultradian dynamics of sleep.

Heglum H, Drews H, Kallestad H, Vethe D, Langsrud K, Sand T J Sleep Res. 2022; 31(6):e13687.

PMID: 35794011 PMC: 9786343. DOI: 10.1111/jsr.13687.

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