Optical fiber Bragg grating based sensing system of flexible wearable smart sleeve for tracking human arm joint movements

Feng, Yan; Wang, Hao-xiang; Liu, Pengbin; Qin, Hua; Pan, Ruiyun; Zhang, H.; Zhang, Hua

doi:10.1088/1361-6501/acd4d7

Cited by 6 publications

(5 citation statements)

References 23 publications

(25 reference statements)

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“…FBG based wearable systems have been widely researched to monitor various vital physiological parameters of the human body such as heart rate monitoring using smart garment [13,14], probe [15], pad [16], mattress [17][18][19], respiratory rate monitoring using smart garment [13,20], conventional oxygen cannulas [21], resistive strip [22], body temperature monitoring using FBG temperature sensors [23], smart garment [12], body postures monitoring during sleep using smart pillow [24], smart bed [8], silicon embedded FBG pressure sensors [25], plantar pressure monitoring using pressure sensitive soles [26,27], smart shoe [28], joint movement monitoring [29,30], and blood glucose monitoring using specially developed FBGs [31,32]. The goal of this paper is twofold: first the experimental characterization of FBG stress sensors is performed to compare with simulated results obtained using OptiSystem software to validate the simulation results.…”

Section: Introductionmentioning

confidence: 99%

Remote monitoring of sleep disorder using FBG sensors and FSO transmission system enabled smart vest

Kanwal,

Atieh,

Ghafoor

et al. 2024

Eng. Res. Express

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Optical sensors, particularly ﬁber Bragg grating (FBG) sensors have achieved a fast ingress into the ﬁelds of medical diagnostic and vital signs monitoring. Wearable smart textiles equipped with FBG sensors are catching huge research attention in different applications for measurement and monitoring of physiological parameters. In this paper, we report a simple technique for remote monitoring of sleep disorder using a smart vest implemented with four FBG stress sensors located at different sides of the vest and free space optics (FSO) transmission system. The sleep disorder of the patient is monitored in real time through shifts in the original Bragg wavelengths of sensors by stress loading during random changes in patient’s sleeping postures. The reﬂected wavelength from a stress loaded sensor at a certain posture is transmitted over 0.5 km long FSO channel towards remote medical center, photodetected, and then can be processed in a PC to record the restlessness in a certain time interval in terms of total number of times sleeping postures are changed, total time spent at a certain posture etc. To correctly detect the stress loaded FBG sensor at the medical center, various parameters of FBG sensors and demultiplexer are carefully adjusted to minimize the power leakages from unloaded sensors that may result into errors in the detection. Maximum dynamic range around 45 dB has been achieved ensuring accurate detection. This study not only provides a cost-efﬁcient and non-intrusive solution for monitoring the sleep disorder of patients but also can be used for real-time monitoring of various other ailments, such as lung, brain, and cardiac diseases in future.

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Section: Introductionmentioning

confidence: 99%

Remote monitoring of sleep disorder using FBG sensors and FSO transmission system enabled smart vest

Kanwal,

Atieh,

Ghafoor

et al. 2024

Eng. Res. Express

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“…The external pressure is amplified through the rhomboid metal structure and acts on both ends of the grating, ensuring high measurement accuracy and the good long-term stability of the sensor [ 5 ]; Lu Xingzhi et al proposed a demodulation method of an FBG sensing system based on nonlinear wavelength drift calibration with an F-P standard to solve the problem of an insufficient demodulation accuracy of the FBG demodulation system due to wavelength drift under variable temperature environments [ 6 ]. Long Yuheng et al proposed a flexible single “cross” and double “cross” touch sliding sensing composite sensor based on FBG that can effectively distinguish sliding signals [ 7 ]; Feng Yue et al designed a soft finger tactile sensing system based on FBG to realize surface texture recognition, reconstruction, and object hardness recognition [ 8 ].…”

Section: Introductionmentioning

confidence: 99%

Research on Convex Fiber Grating Tactile Sliding Sensor Based on Mechanical Fingers

Lu,

Fu,

2024

Sensors

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In order to solve the problem of flexible sliding tactile composite sensing in the actual grasp of intelligent robot fingers, this paper proposes a research on a convex fiber grating tactile sliding sensor based on mechanical fingers. Based on the sensing principle of fiber Bragg grating, 3D printing technology was used to encapsulate the FBG sensor array with elastic 50 A resin, a double-layer “hemispherical cuboid” distributed sensing unit was designed, and the FBG slippery tactile sensor was actually pasted on the surface of the mechanical finger for static and dynamic experiments. The experimental results show that the slippery tactile sensor designed in this paper has a good linear relationship with temperature and strain. The temperature sensitivities of the polymer-packaged FBGs are KT1 = 13.04 pm/°C and KT2 = 12.91 pm/°C, and they have a pressure sensitivity of 40.4 pm/N and 31.2 pm/N, respectively. The FBG sliding tactile sensor not only realizes the identification of the sliding signal generation point and the end point but also completes the classification and identification of sandpaper, cardboard, and polypropylene plastic, and it has a high degree of fit with the robot finger, which has certain application value for the intelligent robot sliding tactile signal perception.

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“…In general, the sensing mechanisms of pressure sensor can be classified into four typical categories: piezoelectricity [7][8][9], piezo-resistance [10][11][12], optics [13][14][15] and capacitance [16][17][18]. Among these mechanisms, extensive researches on capacitive implementation have been widely carried out due to its fast response time, considerable stability, durability and economic efficiency.…”

Section: Introductionmentioning

confidence: 99%

A soft tactile sensing array with high sensitivity based on MWCNTs-PDMS composite of hierarchically porous structure

Yu,

Yao,

Lin

et al. 2023

Smart Mater. Struct.

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The advancement of wearable tactile sensors that involves with high sensitivity under ultra-low pressures is crucial for varieties of human-machine interactive applications, like smart phones, healthcare monitoring, and electronic skins. Here in this paper, a soft capacitive tactile sensing array is introduced based on hierarchically porous multi-walled carbon nanotubes (MWCNTs)-polydimethylsiloxane composite, which leads to sensitivity improvement attributing to a synergistic effect of the hierarchically porous elastomer and conductive MWCNTs supplements. The proposed device exhibits superior pressure-sensing performances, with high sensitivity (3.58 kPa−1) under small mechanical stimuli (<80 Pa), broad measuring range (0–265 kPa), fast response time (<45 ms), good repeatability, minimum limit of detection (<10 Pa), as well as low-hysteresis, allowing efficient sensing of pressure from all types of sources, from vulnerable signals such as human breathing, artery and venous pulses, and soft human finger touch to possible brutal variations such as sudden change of object weight or prompt collide. Moreover, extensive body attached experiments confirm that the soft tactile sensing array is fully human compatible and capable for a variety of human-machine interfaces and health monitoring applications.

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Optical fiber Bragg grating based sensing system of flexible wearable smart sleeve for tracking human arm joint movements

Cited by 6 publications

References 23 publications

Remote monitoring of sleep disorder using FBG sensors and FSO transmission system enabled smart vest

Remote monitoring of sleep disorder using FBG sensors and FSO transmission system enabled smart vest

Research on Convex Fiber Grating Tactile Sliding Sensor Based on Mechanical Fingers

A soft tactile sensing array with high sensitivity based on MWCNTs-PDMS composite of hierarchically porous structure

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