Non-Contact Vital Signs Monitoring Through Visible Light Sensing

Abuella, Hisham; Ekin, Sabit

doi:10.1109/jsen.2019.2960194

Cited by 25 publications

(19 citation statements)

References 60 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…An RR and HR monitoring system based on visible light sensing (VLS) Abuella and Ekin (2018) included the photodetector sensor that measures the power spectrum of reflected signals from the subject's body. Compared with the standard pulse oximeter, the proposed system achieved 94% accuracy for RR and HR measurements.…”

Section: Related Workmentioning

confidence: 99%

MobiEye: turning your smartphones into a ubiquitous unobtrusive vital sign monitoring system

Patil

Wang

Gao

et al. 2020

CCF Trans. Pervasive Comp. Interact.

View full text Add to dashboard Cite

Recent advances in mobile and wearable technologies have stimulated significantly growing demands for more affordable, user-friendly, pervasive healthcare solutions that can be adopted by the public to proactively manage their health conditions and alleviate the burdens of hospitalization. This study seeks to propose a personalized ubiquitous health monitoring system that can unobtrusively monitor individuals' vital signs, anywhere at any time. The proposed MobiEye framework makes use of the regular camera available on any smartphones or tablets to record various most important physiological signals without the need for acquiring extra specialized medical devices or attaching any sensor to the body. Through recording the reflected light intensities corresponding to the subtle blood flow changes with blood volume pulses, the proposed technique accurately extracts blood volume pulses from the facial videos recorded in real-world scenarios with the designed protocol. Experiments show that the proposed system achieved 96 % accuracy on average (with the standard deviations of ±1.2) for the heart rate estimation and higher correlations between the pulse transit time and the reference systolic blood pressure (mean r = 0.89, SE = 0.05).

show abstract

Section: Related Workmentioning

confidence: 99%

MobiEye: turning your smartphones into a ubiquitous unobtrusive vital sign monitoring system

Patil

Wang

Gao

et al. 2020

CCF Trans. Pervasive Comp. Interact.

View full text Add to dashboard Cite

show abstract

“…Finally, referring to the methods based on modulation of other physiological signals, the well-known ECG-derived respiration (EDR) [57,58] measures ECG morphology changes due to sinus arrhythmia, relative movement of heart and electrodes and changes in lung volume, whereas the photoplethysmography (PPG)-derived respiration exploits the modulation in amplitude, baseline and frequency of the PPG signal caused by changes in blood stroke volume, heart rate and tissue blood volume and the variation of its pulse wave width under changes in artery stiffness during the respiratory activity [59,60]. On the other hand, contactless techniques comprise methods based on environmental respiratory sounds (e.g., microphones), air temperature (e.g., thermal cameras), chest wall movements (e.g., radar sensors, marker-based stereophotogrammetric systems, stereoscopic camera sensors) or modulation of other physiological signals (e.g., light intensity measurement, RGB cameras) [8,[61][62][63][64][65][66][67][68][69][70][71][72][73][74]. The great part of the instrumentation required by such methods is generally cumbersome and far from being wearable, or even portable, so its use has remained confined to research or clinical settings [1,2].…”

Section: Introductionmentioning

confidence: 99%

Respiration Monitoring via Forcecardiography Sensors

Andreozzi

Centracchio

Punzo

et al. 2021

Sensors

View full text Add to dashboard Cite

In the last few decades, a number of wearable systems for respiration monitoring that help to significantly reduce patients’ discomfort and improve the reliability of measurements have been presented. A recent research trend in biosignal acquisition is focusing on the development of monolithic sensors for monitoring multiple vital signs, which could improve the simultaneous recording of different physiological data. This study presents a performance analysis of respiration monitoring performed via forcecardiography (FCG) sensors, as compared to ECG-derived respiration (EDR) and electroresistive respiration band (ERB), which was assumed as the reference. FCG is a novel technique that records the cardiac-induced vibrations of the chest wall via specific force sensors, which provide seismocardiogram-like information, along with a novel component that seems to be related to the ventricular volume variations. Simultaneous acquisitions were obtained from seven healthy subjects at rest, during both quiet breathing and forced respiration at higher and lower rates. The raw FCG sensor signals featured a large, low-frequency, respiratory component (R-FCG), in addition to the common FCG signal. Statistical analyses of R-FCG, EDR and ERB signals showed that FCG sensors ensure a more sensitive and precise detection of respiratory acts than EDR (sensitivity: 100% vs. 95.8%, positive predictive value: 98.9% vs. 92.5%), as well as a superior accuracy and precision in interbreath interval measurement (linear regression slopes and intercepts: 0.99, 0.026 s (R2 = 0.98) vs. 0.98, 0.11 s (R2 = 0.88), Bland–Altman limits of agreement: ±0.61 s vs. ±1.5 s). This study represents a first proof of concept for the simultaneous recording of respiration signals and forcecardiograms with a single, local, small, unobtrusive, cheap sensor. This would extend the scope of FCG to monitoring multiple vital signs, as well as to the analysis of cardiorespiratory interactions, also paving the way for the continuous, long-term monitoring of patients with heart and pulmonary diseases.

show abstract

“…To extend the potentials of VLS, these surfaces can be coated with codes, this means sequences of surface areas with different reflectivity values or different colors, which supports the identification of an object, its positon or a movement of the object [14] [15]. Applications of VLS range from presence detection [16], pose detection [17] occupancy estimation [18], and hand gesture recognition [19] [20] to vital sign monitoring [21]. Especially in scenarios in which human beings are involved, VLS has the advantage that it does not provide privacy concerns.…”

Section: Introductionmentioning

confidence: 99%

Machine Learning Assisted Visible Light Sensing of the Rotation of a Robotic Arm

et al. 2021

View full text Add to dashboard Cite

With the rise of LED (light-emitting diode)-based luminaires, artificial lighting has become a technology platform, which, besides providing illumination, also provides communication and positioning functionalities. Apart from this, most recently Visible Light Sensing (VLS), in which lighting is used for sensing purposes, emerged as another embodiment of functionalities lighting could take over in the future.Here we show that machine learning assisted VLS has promising potentials to become a meaningful enabler for the industrial internet of things. We show that the motion of a robotic arm can be accurately monitored by VLS simply by equipping the robotic arm with sequences of colored retroreflective foils. Moreover, we show that the sensing task is compatible with a modulation of the light. This paths the way that sensing and communication tasks can be performed with one and the same low-complexity infrastructure, that apart from this also could take over the task of the obligatory room lighting. We demonstrate the capability of the approach even if the illumination conditions change. Therewith, VLS accentuates as an alternative option for industrial robot monitoring in combination with optical wireless communication.

show abstract

Non-Contact Vital Signs Monitoring Through Visible Light Sensing

Cited by 25 publications

References 60 publications

MobiEye: turning your smartphones into a ubiquitous unobtrusive vital sign monitoring system

MobiEye: turning your smartphones into a ubiquitous unobtrusive vital sign monitoring system

Respiration Monitoring via Forcecardiography Sensors

Machine Learning Assisted Visible Light Sensing of the Rotation of a Robotic Arm

Contact Info

Product

Resources

About