A dual-band dual-polarized omnidirectional patch antenna for on-body application

Guo Ping Gao; Dan Wang; Ge Ma; Shi Chen Wang; Zhi Heng Dou; Bin Hu

doi:10.1002/mop.34050

A dual-band dual-polarized omnidirectional patch antenna for on-body application

Guo Ping Gao, Dan Wang, Ge Ma, Shi Chen Wang, Zhi Heng Dou, Bin Hu^*

^*Corresponding author for this work

Lanzhou University

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

Aiming at the 3.5 GHz world interoperability for microwave access band and 5.8 GHz industrial scientific medical band, a dual-band antenna operating in omnidirectional mode is proposed. The antenna uses a single-layer dielectric substrate made of FR-4, which is cheap and easy to process. It uses circular patches and metal branches to generate orthogonal electric fields to achieve circular polarization. At the same time, the upper patch is symmetrically slotted in a T shape, so that the patch produces two resonance frequencies. The measured impedance bandwidth of the antenna in circular polarization on-body mode and linear polarization on-body mode is 110 MHz (3.41–3.52 GHz) and 460 MHz (5.42–5.88 GHz), respectively. In addition, the antenna shows good performance under bending conditions and close to human tissue. At the same time, the low specific absorption rate value proves that the antenna is safe to wear on the human body.

Original language	English
Article number	e34050
Journal	Microwave and Optical Technology Letters
Volume	66
Issue number	3
DOIs	https://doi.org/10.1002/mop.34050
Publication status	Published - Mar 2024
Externally published	Yes

Keywords

circular polarization
dual-band dual-polarized antenna
linear polarization
omnidirectional mode
on-body

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10.1002/mop.34050

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title = "A dual-band dual-polarized omnidirectional patch antenna for on-body application",

abstract = "Aiming at the 3.5 GHz world interoperability for microwave access band and 5.8 GHz industrial scientific medical band, a dual-band antenna operating in omnidirectional mode is proposed. The antenna uses a single-layer dielectric substrate made of FR-4, which is cheap and easy to process. It uses circular patches and metal branches to generate orthogonal electric fields to achieve circular polarization. At the same time, the upper patch is symmetrically slotted in a T shape, so that the patch produces two resonance frequencies. The measured impedance bandwidth of the antenna in circular polarization on-body mode and linear polarization on-body mode is 110 MHz (3.41–3.52 GHz) and 460 MHz (5.42–5.88 GHz), respectively. In addition, the antenna shows good performance under bending conditions and close to human tissue. At the same time, the low specific absorption rate value proves that the antenna is safe to wear on the human body.",

keywords = "circular polarization, dual-band dual-polarized antenna, linear polarization, omnidirectional mode, on-body",

author = "Gao, {Guo Ping} and Dan Wang and Ge Ma and Wang, {Shi Chen} and Dou, {Zhi Heng} and Bin Hu",

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year = "2024",

month = mar,

doi = "10.1002/mop.34050",

language = "English",

volume = "66",

journal = "Microwave and Optical Technology Letters",

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T1 - A dual-band dual-polarized omnidirectional patch antenna for on-body application

AU - Gao, Guo Ping

AU - Wang, Dan

AU - Ma, Ge

AU - Wang, Shi Chen

AU - Dou, Zhi Heng

AU - Hu, Bin

PY - 2024/3

Y1 - 2024/3

N2 - Aiming at the 3.5 GHz world interoperability for microwave access band and 5.8 GHz industrial scientific medical band, a dual-band antenna operating in omnidirectional mode is proposed. The antenna uses a single-layer dielectric substrate made of FR-4, which is cheap and easy to process. It uses circular patches and metal branches to generate orthogonal electric fields to achieve circular polarization. At the same time, the upper patch is symmetrically slotted in a T shape, so that the patch produces two resonance frequencies. The measured impedance bandwidth of the antenna in circular polarization on-body mode and linear polarization on-body mode is 110 MHz (3.41–3.52 GHz) and 460 MHz (5.42–5.88 GHz), respectively. In addition, the antenna shows good performance under bending conditions and close to human tissue. At the same time, the low specific absorption rate value proves that the antenna is safe to wear on the human body.

AB - Aiming at the 3.5 GHz world interoperability for microwave access band and 5.8 GHz industrial scientific medical band, a dual-band antenna operating in omnidirectional mode is proposed. The antenna uses a single-layer dielectric substrate made of FR-4, which is cheap and easy to process. It uses circular patches and metal branches to generate orthogonal electric fields to achieve circular polarization. At the same time, the upper patch is symmetrically slotted in a T shape, so that the patch produces two resonance frequencies. The measured impedance bandwidth of the antenna in circular polarization on-body mode and linear polarization on-body mode is 110 MHz (3.41–3.52 GHz) and 460 MHz (5.42–5.88 GHz), respectively. In addition, the antenna shows good performance under bending conditions and close to human tissue. At the same time, the low specific absorption rate value proves that the antenna is safe to wear on the human body.

KW - circular polarization

KW - dual-band dual-polarized antenna

KW - linear polarization

KW - omnidirectional mode

KW - on-body

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U2 - 10.1002/mop.34050

DO - 10.1002/mop.34050

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SN - 0895-2477

VL - 66

JO - Microwave and Optical Technology Letters

JF - Microwave and Optical Technology Letters

IS - 3

M1 - e34050

ER -

A dual-band dual-polarized omnidirectional patch antenna for on-body application

Abstract

Keywords

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