Broadband, miniaturized stacked-patch antennas for L-band operation based on magneto-dielectric substrates

Farhad Namin; Thomas G. Spence; Douglas H. Werner; Elena Semouchkina

doi:10.1109/TAP.2010.2052574

Broadband, miniaturized stacked-patch antennas for L-band operation based on magneto-dielectric substrates

Farhad Namin
, Thomas G. Spence
, Douglas H. Werner
, Elena Semouchkina

Electrical Engineering

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

36 Scopus citations

Abstract

Design of stacked-patch antennas using magneto-dielectric substrates was investigated. In particular, special types of substrates with identical relative permittivity and permeability were considered. The optimal design parameters were determined using a genetic algorithm. It will be shown that by employing these matched magneto-dielectric substrates, a significant miniaturization of up to 60% can be achieved while providing a large operating bandwidth (20%). Several design examples were considered and their performance was evaluated using a full-wave analysis technique based on the method of moments. The tradeoff between antenna gain and degree of miniaturization for a fixed bandwidth was also investigated. A fabrication methodology for obtaining the required matched magneto-dielectric substrate materials is also proposed.

Original language	English (US)
Article number	5484644
Pages (from-to)	2817-2822
Number of pages	6
Journal	IEEE Transactions on Antennas and Propagation
Volume	58
Issue number	9
DOIs	https://doi.org/10.1109/TAP.2010.2052574
State	Published - Sep 2010

All Science Journal Classification (ASJC) codes

Electrical and Electronic Engineering

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10.1109/TAP.2010.2052574

Cite this

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title = "Broadband, miniaturized stacked-patch antennas for L-band operation based on magneto-dielectric substrates",

abstract = "Design of stacked-patch antennas using magneto-dielectric substrates was investigated. In particular, special types of substrates with identical relative permittivity and permeability were considered. The optimal design parameters were determined using a genetic algorithm. It will be shown that by employing these matched magneto-dielectric substrates, a significant miniaturization of up to 60\% can be achieved while providing a large operating bandwidth (20\%). Several design examples were considered and their performance was evaluated using a full-wave analysis technique based on the method of moments. The tradeoff between antenna gain and degree of miniaturization for a fixed bandwidth was also investigated. A fabrication methodology for obtaining the required matched magneto-dielectric substrate materials is also proposed.",

author = "Farhad Namin and Spence, \{Thomas G.\} and Werner, \{Douglas H.\} and Elena Semouchkina",

note = "Funding Information: Mr. Namin is the recipient of the Exploratory and Foundational Program Fellowship from the Applied Research Laboratory (ARL) at The Pennsylvania State University.",

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AU - Namin, Farhad

AU - Spence, Thomas G.

AU - Werner, Douglas H.

AU - Semouchkina, Elena

N1 - Funding Information: Mr. Namin is the recipient of the Exploratory and Foundational Program Fellowship from the Applied Research Laboratory (ARL) at The Pennsylvania State University.

PY - 2010/9

Y1 - 2010/9

N2 - Design of stacked-patch antennas using magneto-dielectric substrates was investigated. In particular, special types of substrates with identical relative permittivity and permeability were considered. The optimal design parameters were determined using a genetic algorithm. It will be shown that by employing these matched magneto-dielectric substrates, a significant miniaturization of up to 60% can be achieved while providing a large operating bandwidth (20%). Several design examples were considered and their performance was evaluated using a full-wave analysis technique based on the method of moments. The tradeoff between antenna gain and degree of miniaturization for a fixed bandwidth was also investigated. A fabrication methodology for obtaining the required matched magneto-dielectric substrate materials is also proposed.

AB - Design of stacked-patch antennas using magneto-dielectric substrates was investigated. In particular, special types of substrates with identical relative permittivity and permeability were considered. The optimal design parameters were determined using a genetic algorithm. It will be shown that by employing these matched magneto-dielectric substrates, a significant miniaturization of up to 60% can be achieved while providing a large operating bandwidth (20%). Several design examples were considered and their performance was evaluated using a full-wave analysis technique based on the method of moments. The tradeoff between antenna gain and degree of miniaturization for a fixed bandwidth was also investigated. A fabrication methodology for obtaining the required matched magneto-dielectric substrate materials is also proposed.

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Broadband, miniaturized stacked-patch antennas for L-band operation based on magneto-dielectric substrates

Abstract

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