Wearable Sensing of In-Ear Pressure for Heart Rate Monitoring with a Piezoelectric Sensor

Park, Jang-Ho; Jang, Dae-Geun; Park, Jung–Wook; Youm, Sekyoung

doi:10.3390/s150923402

Cited by 78 publications

(58 citation statements)

References 24 publications

(28 reference statements)

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“…HR measurements between ECG and earpiece HR monitor almost completely overlapped each other (Leboeuf, et al, 2014). In addition, Park et al (2015) identified an earpiece HR monitoring device to be VOLUME 13 | ISSUE 3 | 2018 | 533 significantly accurate across various intensities of exercise. However, several limitations may occur with earpiece devices, including skin irritation, difficulties connecting to additional devices, bulky sensors and hygiene (Chan, Estève, Fourniols, Escriba, & Campo, 2012).…”

Section: Introductionmentioning

confidence: 94%

“…The absence of bone and predominantly compromising of cartilage and blood suggests the ear is suitable for continuous HR monitoring with photoplethysmography (PPG) (Budidha & Kyriacou, 2014;Park, Jang, Park, & Youm, 2015). The length of the ear canal is roughly 2.5cm, with a diameter of approximately 7mm with exceedingly sensitive skin, (Park et al, 2015), with PPG technology, the earpiece sensors detect how much light is reflected from the subcutaneous blood vessels (Budidha & Kyriacou, 2014). PPG uses optoelectronic features to isolate red and infrared wavelengths and light refraction to dictate blood flow (Schafer & Vagedes, 2013;Spierer, et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

“…Furthermore, the sensors have been reported to become displaced, that HR measurements can be disrupted via noise and low light levels and for wires to cause distress and pain (Aarts et al, 2013). In relation to the accuracy and convenience of earpiece devices (Leboeuf, et al, 2014;Park, et al, 2015)and limitations identified (Aarts, et al, 2013), Spierer et al (2015) suggests further research to validate earpiece HR monitoring devices using PPG technology, is required.…”

Section: Introductionmentioning

confidence: 99%

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Comparisons in heart rate readings between the Bioconnected wireless exercise earpiece and a Polar T31-Coded Chest Strap during a GXT

Higgins

Lloyd

Manalansan

et al. 2018

jhse

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Purpose. The advent of mobile technology has provided a convenient method of measuring heart rate in clinical settings and athletic training with limited support. Therefore the purpose of this research was to evaluate the validity of an earpiece HR monitoring device against a previously validated chest strap HR monitoring device. Method. A convenient sample of college students (n=15), performing a modified Bruce protocol, provided 25 data samples. Heart rates obtained from both the Bioconnected wireless exercise earpieces and a Polar T31-Coded Chest Strap where compared by correlation and coefficient. The Bioconnected wireless exercise earpieces were considered to be valid if the correlation between the recorded heart rate of the Bioconnected device and the corresponding heart rate Polar T31-Coded Chest Strap measurement was r ≥0.90. Results. Five samples were corrupted due to displacement of chest strap (n=3) and dislodgement of earpiece (n=2) during testing, as such data from those tests were excluded from the correlation analysis. The remaining 20 data samples provided mean totals of 521±117 HR data points (earpiece) and 517±118 HR data points (chest strap). A strong correlation (r=0.97) between the Bioconnected wireless exercise earpieces and a Polar T31-Coded Chest Strap. Conclusions. The results of this study show that the HR measurements of the Bioconnected wireless exercise earpieces and the Polar Chest Strap are highly correlated, supporting the Bioconnected wireless exercise earpieces in monitoring HR during a GXT on a treadmill in healthy adults. However, as exercise transitioned from walking to jogging, at times, both devices had problems with displacement and loss of HR signal, suggesting the need for improved

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Section: Introductionmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Comparisons in heart rate readings between the Bioconnected wireless exercise earpiece and a Polar T31-Coded Chest Strap during a GXT

Higgins

Lloyd

Manalansan

et al. 2018

jhse

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“…Various applications have been developed to measure vital signs by means of piezoelectric material45678. A piezoelectric based system has been developed to monitor respiration rate7, heart rate456, and seismocardiography8.…”

mentioning

confidence: 99%

“…A piezoelectric based system has been developed to monitor respiration rate7, heart rate456, and seismocardiography8. This paper presents a novel technique for the reconstruction of the ECG corresponding signal from a measured piezoelectric output voltage signal.…”

mentioning

confidence: 99%

Piezoelectric extraction of ECG signal

Ahmad

2016

Sci Rep

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The monitoring and early detection of abnormalities or variations in the cardiac cycle functionality are very critical practices and have significant impact on the prevention of heart diseases and their associated complications. Currently, in the field of biomedical engineering, there is a growing need for devices capable of measuring and monitoring a wide range of cardiac cycle parameters continuously, effectively and on a real-time basis using easily accessible and reusable probes. In this paper, the revolutionary generation and extraction of the corresponding ECG signal using a piezoelectric transducer as alternative for the ECG will be discussed. The piezoelectric transducer pick up the vibrations from the heart beats and convert them into electrical output signals. To this end, piezoelectric and signal processing techniques were employed to extract the ECG corresponding signal from the piezoelectric output voltage signal. The measured electrode based and the extracted piezoelectric based ECG traces are well corroborated. Their peaks amplitudes and locations are well aligned with each other.

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