An Optimized Wearable Textile Antenna Using Surrogate Ensemble Learning for ISM On-Body Communications

In this paper, a novel microstrip antenna for the new ISM band (24 GHz - 25 GHz) with a flexible substrate is proposed. This antenna has a small dimension, high gain, and large bandwidth in the ISM band. Several tests such as bending tests, and gas environment tests are performed to show the potenti...

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Bibliographic Details
Published in:IEEE transactions on components, packaging, and manufacturing technology (2011) packaging, and manufacturing technology (2011), 2023-08, Vol.13 (8), p.1-1
Main Authors: Jafarieh, A., Nouri, M., Noorollahi, H., Behroozi, H., Mallat, N. K.
Format: Article
Language:English
Subjects:
5G mobile communication
Antenna gain
Antennas
Bending
Body area networks
Ensemble learning
Evolutionary algorithms
flexible antenna
Gain
Ground plane
High gain
ISM band
Machine learning
Microstrip antennas
Millimeter wave communication
mmWave
Monopole antennas
Optimization
Substrates
wearable antenna
Wearable antennas
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Summary:In this paper, a novel microstrip antenna for the new ISM band (24 GHz - 25 GHz) with a flexible substrate is proposed. This antenna has a small dimension, high gain, and large bandwidth in the ISM band. Several tests such as bending tests, and gas environment tests are performed to show the potential of the antenna in body area networks (BANs) applications. The design procedure starts with a simple monopole antenna with a simple ground plane. Then, to change the effective permittivity of the substrate an array of half circles is subtracted from the ground plane. To avoid increasing the dimension of the antenna, a triangular part and a shunt are added to the monopole antenna. By doing this, the resonance frequency of the antenna is changed without changing its overall dimension. The theoretical bases for creating an initial antenna are discussed to achieve the values of the initial antenna. Then, to achieve an optimum antenna, the initial antenna is treated with a machine learning approach with the goal of maximizing antenna gain and bandwidth. The so-called DDEA-SE (data-driven evolutionary algorithm based on selective ensemble) is used as the machine learning approach. The optimum antenna has 1.8 GHz ( 7.6% IBW) bandwidth which covers the 24 GHz - 25.8 GHz band. The optimum antenna has a 4.9 dBi maximum realized gain on 25 GHz frequency. The optimization procedure increased the average gain of the antenna near 1 dB and the bandwidth of the antenna near 500 MHz with respect to the initial antenna.
ISSN:2156-3950
2156-3985
DOI:10.1109/TCPMT.2023.3303194