Validation of a Body-Conducted Sound Sensor for Respiratory Sound Monitoring and a Comparison with Several Sensors

Wearable light textiles are gaining widespread interest in application for measurement and monitoring of biophysical parameters. Fiber optic sensors, in particular Bragg Grating (FBG) sensors, can be a competitive method for monitoring of respiratory behavior for chest and abdomen regions since the sensors are able to convert physical movement into wavelength shift. This study aims to show the performance of elastic belts with integrated optical fibers during the breathing activities done by two volunteers. Additionally, the work aims to determine how the positions of the volunteers affect the breathing pattern detected by optical fibers. As a reference, commercial mobile application for sensing vibration is used. The obtained results show that the FBGs are able to detect chest and abdomen movements during breathing and consequently reconstruct the breathing pattern. The accuracy of the results varies for two volunteers but remains consistent.

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“…(1) Convert wavelength pattern per time to the strain change by using Equation (2). Since temperature in this experiment is constant, ∆T is 0.…”

Section: Algorithm For the Breathing Pattern Reconstructionmentioning

confidence: 99%

“…Joyashiki and Wada [ 2 ] proposed to monitor breathing pattern by a body-conducted sound sensor placed on the neck. The performance of the sensor was compared with two other sensors, namely air-coupled microphone and acceleration sensor.…”

Section: Introductionmentioning

confidence: 99%

Fiber-Optic Based Smart Textiles for Real-Time Monitoring of Breathing Rate

Issatayeva

Beisenova

Tosi

et al. 2020

Sensors

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“…Outside of these existing solutions, there have been several proposed new device designs that would enable comfortable and continuous health monitoring via acoustic signals. , One general approach is to combine a typical off-the-shelf microphone with an acoustic impedance matching layer, − which improves the device sensitivity and noise rejection. Several studies have also used off-the-shelf accelerometers with encapsulation in an elastomer that incorporates soft and stretchable electronics, , while another developed a new ultrasensitive and wideband accelerometer that cannot be fabricated with conventional methods .…”

Section: Introductionmentioning

confidence: 99%

Electrostatic Acoustic Sensor with an Impedance-Matched Diaphragm Characterized for Body Sound Monitoring

Rennoll

McLane

Eisape

et al. 2023

ACS Appl. Bio Mater.

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Acoustic sensors are able to capture more incident energy if their acoustic impedance closely matches the acoustic impedance of the medium being probed, such as skin or wood. Controlling the acoustic impedance of polymers can be achieved by selecting materials with appropriate densities and stiffnesses as well as adding ceramic nanoparticles. This study follows a statistical methodology to examine the impact of polymer type and nanoparticle addition on the fabrication of acoustic sensors with desired acoustic impedances in the range of 1−2.2 MRayls. The proposed method using a design of experiments approach measures sensors with diaphragms of varying impedances when excited with acoustic vibrations traveling through wood, gelatin, and plastic. The sensor diaphragm is subsequently optimized for body sound monitoring, and the sensor's improved body sound coherence and airborne noise rejection are evaluated on an acoustic phantom in simulated noise environments and compared to electronic stethoscopes with onboard noise cancellation. The impedance-matched sensor demonstrates high sensitivity to body sounds, low sensitivity to airborne sound, a frequency response comparable to two state-of-the-art electronic stethoscopes, and the ability to capture lung and heart sounds from a real subject. Due to its small size, use of flexible materials, and rejection of airborne noise, the sensor provides an improved solution for wearable body sound monitoring, as well as sensing from other mediums with acoustic impedances in the range of 1−2.2 MRayls, such as water and wood.

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“…And most of these technology monitor the breath state by measuring many other parameters, such as detecting sounds of breath, humidity of air flow, pressure differential, chest vibration and so on. These technology often need complex equipment and can not monitor respiratory state directly [10] , [11] , [12] , [13] , [14] , [15] . There is a tremendous need to develope a more simple and portable respiratory monitoring equipment which can identify a respiratory infection early—before a worker or student feels ill.…”

Section: Introductionmentioning

confidence: 99%

Intelligent facemask based on triboelectric nanogenerator for respiratory monitoring

Chen

Zeng

et al. 2022

Nano Energy

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The fast-spreading of novel coronavirus disease (COVID-19) has been sweeping arount the globe and brought heavy casualties and economic losses, which creats dire needs for technological solutions into medical preventive actions. In this work, triboelectric nanogenerator for respiratory sensing (RS-TENG) has been designed and integrated with facemask, which endows the latter with respiratory monitoring function. The output of RS-TENG for respiratory flow can reach up to about 8 V and 0.8 μA respectively although it varies with different respiratory status, which proves the high sensitivity of RS-TENG for respiratory monitoring. An apnea alarm system can be constructed by combining the smart facemask with circuit modules so that timely alarm can be transmitted after people stop breathing. Furthermore, RS-TENG can be used to control household appliances, which brings convenience to the life of the disabled people. Considering its incomparable advantages such as small volume, easy fabrication, simple installation and economical applicability, such design is helpful for developing multifunctional health monitoring gadgets during the COVID-19 pandemic.

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Validation of a Body-Conducted Sound Sensor for Respiratory Sound Monitoring and a Comparison with Several Sensors

Cited by 14 publications

References 38 publications

Fiber-Optic Based Smart Textiles for Real-Time Monitoring of Breathing Rate

Fiber-Optic Based Smart Textiles for Real-Time Monitoring of Breathing Rate

Electrostatic Acoustic Sensor with an Impedance-Matched Diaphragm Characterized for Body Sound Monitoring

Intelligent facemask based on triboelectric nanogenerator for respiratory monitoring

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