Metasurface-Inspired Flexible Wearable MIMO Antenna Array for Wireless Body Area Network Applications and Biomedical Telemetry Devices

This article presents a sub-6GHz ISM-band flexible wearable MIMO antenna array for wireless body area networks (WBANs) and biomedical telemetry devices. The array is based on metasurface inspired technology. The antenna array consists of 2×2 matrix of triangular-shaped radiation elements that were r...

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Bibliographic Details
Published in:IEEE access 2023-01, Vol.11, p.1-1
Main Authors: Althuwayb, Ayman A., Alibakhshikenari, Mohammad, Virdee, Bal S., Rashid, Nasr, Kaaniche, Khaled, Atitallah, Ahmed Ben, Armghan, Ammar, Elhamrawy, Osama I., See, Chan Hwan, Falcone, Francisco
Format: Article
Language:English
Subjects:
Antenna arrays
Antennas
Bending
Biomedical materials
Biomedical monitoring
biomedical telemetry devices
Body area networks
Circuits
Decoupling
Design optimization
Efficiency
electromagnetic bandgap (EBG) devices
Engineering Sciences
flexible antennas
metasurface (MTS) antennas
Metasurfaces
MIMO antenna array
MIMO communication
On-body antennas
Periodic structures
Radiation
Radiators
Substrates
Telemetry
wearable antennas
Wearable technology
wireless body area network (WBAN)
Wireless communication
Wireless networks
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Summary:This article presents a sub-6GHz ISM-band flexible wearable MIMO antenna array for wireless body area networks (WBANs) and biomedical telemetry devices. The array is based on metasurface inspired technology. The antenna array consists of 2×2 matrix of triangular-shaped radiation elements that were realized on 0.8 mm thick Rogers RT/duroid 5880 substrate. Radiation characteristics of the array are enhanced by isolating the surface current interaction between the individual radiators in the array. This is achieved by inserting an electromagnetic bandgap (EBG) decoupling structure between the radiating elements. The radiating elements were transformed into a metasurface by etching sub-wavelength slots inside them. The periodic arrangement of slots acts like resonant scatterers that manipulate the electromagnetic response of the surface. Results confirm that by employing the decoupling structure and sub-wavelength slots the isolation between the radiators is significantly improved (>34.8 dB). Moreover, there is an improvement in the array's fractional bandwidth, gain and the radiation efficiency. The optimized array design for operation over 5.0-6.6 GHz has an average gain and efficiency of 10 dBi and 83%, respectively. Results show that the array's performance is not greatly affected by a certain amount of bending. In fact, the antenna maintains a gain between 8.65-10.5 dBi and the efficiency between 77-83%. The proposed MIMO antenna array is relatively compact, can be easily fabricated on one side of a dielectric material, allows easy integration with RF circuitry, is robust, and maintains its characteristics with some bending. These features make it suitable for various wearable applications and biomedical telemetry devices.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2022.3233388