Dual-band Patch Antenna Matching Network comprised of Separated Ground Layers and Via Posts for Adjustable Return Current Path

This paper proposes a dual-band antenna impedance matching network concept that features identical radiation characteristics. The concept is exemplified for millimeter-wave mobile devices but can be scaled to lower and higher frequency spectrum. The method is deduced through an introduction of an ad...

Full description

Saved in:
Bibliographic Details
Published in:IEEE access 2022, Vol.10, p.1-1
Main Authors: Youn, Youngno, Choi, Jaehyun, Kim, Bumhyun, Hwang, Woonbong, Sim, Chow-Yen-Desmond, Hong, Wonbin
Format: Article
Language:English
Subjects:
Antenna radiation patterns
Antennas
Beamforming
Dual band
Electronic devices
Far fields
Frequency measurement
Impedance matching
Impedance matching network
Low temperature
Millimeter wave communication
Millimeter waves
Millimeter-wave antenna
Mobile antennas
Multi-band antenna
Patch antennas
Phased arrays
Reflection coefficient
Resonance
Resonant frequency
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:This paper proposes a dual-band antenna impedance matching network concept that features identical radiation characteristics. The concept is exemplified for millimeter-wave mobile devices but can be scaled to lower and higher frequency spectrum. The method is deduced through an introduction of an additional matching network consisting of inductive distributed elements to formulate adjustable return current paths. This is realized using fragmented ground plane and a series of vias. No modification of the antenna radiating element is required. This new class of matching network enables independent adjustment of the resonance frequencies while maintaining nearly-identical radiation patterns at both frequencies. For experimental verifications, the proposed antenna impedance matching network is fabricated using a low-temperature co-fired ceramic process. The measurement of this single element exhibits dual-band operations at 28.0 GHz and 39.0 GHz, obtaining the realized gain of 5.15 dBi and 5.42 dBi, respectively. In addition, a 1Ă—4 phased array antenna is devised and studied to validate beamforming performances at both frequencies. With the integration of the beamforming circuit, a reconfigurable beamforming is demonstrated at 28.0 GHz, in which the peak measured gain is 10.83 dBi. At the second resonance frequency (39.0 GHz), a passive feeding network is employed to evaluation its beam scanning abilities, and the main beam peak realized gain of 10.40 dBi is ascertained. The result can be extended to any other frequencies while maintaining near-identical far-field characteristics.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2022.3208576