Abu Saleh Tajin scite author profile

One of the major challenges faced by passive on-body wireless Internet of Things (IoT) sensors is the absorption of radiated power by tissues in the human body. We present a battery-less, wearable knitted Ultra High Frequency (UHF, 902-928 MHz) Radio Frequency Identification (RFID) compression sensor (Bellypatch) antenna and show its applicability as an on-body respiratory monitor. The antenna radiation efficiency is satisfactory in both free-space and on-body operations. We extract RF (Radio Frequency) sheet resistance values of three knitted silver-coated nylon fabric candidates at 913 MHz. The best type of fabric is selected based on the extracted RF sheet resistance. Simulated and measured performance of the antenna confirm suitability for on-body applications. The proposed Bellypatch antenna is used to measure the breathing activity of a programmable infant patient emulator mannequin (SimBaby) and a human subject. The antenna is highly sensitive to respiratory compression and relaxation. Fluctuations in the backscatter power level/Received Signal Strength Indicator (RSSI) in both cases range from 6 dB to 15 dB. The improved on-body read range of the proposed sensor antenna is 5.8 m, about 10 times higher than its predecessor wearable knitted strain sensing Bellyband antenna (0.6 m). The maximum simulated Specific Absorption Rate (SAR) on a human torso model is 0.25 W/kg, lower than the maximum allowable limit of 1.6 W/kg.

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On the Effect of Sweat on Sheet Resistance of Knitted Conductive Yarns in Wearable Antenna Design

Tajin

Levitt

Liu

et al. 2020

Antennas Wirel. Propag. Lett.

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Efficiency measurement of the flexible on‐body antenna at varying levels of stretch in a reverberation chamber

Tajin

Bshara

Liu

et al. 2019

IET microw. antennas propagation

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Flexible antennas have the potential to transform wearable and fabric‐based wireless sensing technologies. The antenna discussed in this study is part of a sensing system that uses the back‐scattered power level as the decision metric. For a good wireless sensor, it is necessary to offer a feasible read range and maintain good distinctions in the back‐scattered power levels between the different states (i.e. level of stretch) of the antenna. Moreover, effects due to human body proximity should be minimised. For these reasons, the radiation efficiency is a crucial parameter to investigate. This study presents the radiation efficiency measurement of the proposed flexible knitted ‘Bellyband’ antenna at two different levels of stretch in a reverberation chamber. This work validates the reverberation chamber measurements through comparison with simulations and anechoic chamber measurements at 900 MHz. Moreover, this work demonstrates how the approach can be used to quantify bellyband antenna efficiency in the vicinity of a human body. Finally, the efficiency results were used to predict the read range of Bellyband radio frequency identification technology.

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Abu Saleh Tajin

Solution‐Processed Ti₃C₂T_x MXene Antennas for Radio‐Frequency Communication

Passive RFID-Based Diaper Moisture Sensor

Passive UHF RFID-Based Knitted Wearable Compression Sensor

On the Effect of Sweat on Sheet Resistance of Knitted Conductive Yarns in Wearable Antenna Design

Efficiency measurement of the flexible on‐body antenna at varying levels of stretch in a reverberation chamber

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Abu Saleh Tajin

Solution‐Processed Ti3C2Tx MXene Antennas for Radio‐Frequency Communication

Passive RFID-Based Diaper Moisture Sensor

Passive UHF RFID-Based Knitted Wearable Compression Sensor

On the Effect of Sweat on Sheet Resistance of Knitted Conductive Yarns in Wearable Antenna Design

Efficiency measurement of the flexible on‐body antenna at varying levels of stretch in a reverberation chamber

Contact Info

Product

Resources

About

Solution‐Processed Ti₃C₂T_x MXene Antennas for Radio‐Frequency Communication