Precise control of reflection response in bandwidth-enhanced planar antennas

Adrian Bekasiewicz; Slawomir Koziel

doi:10.1002/mmce.21021

Precise control of reflection response in bandwidth-enhanced planar antennas

Adrian Bekasiewicz^*, Slawomir Koziel

^*Corresponding author for this work

Department of Engineering

Research output: Contribution to journal › Review article › peer-review

3 Citations (Scopus)

Abstract

In this work, the issues of bandwidth enhancement of planar antennas and the relevance of precise and automated response control through numerical optimization have been investigated. Using an example of a planar antenna with parasitic radiator we illustrate possible effects of even minor modifications of the antenna geometry (here, applied to the ground plane) on its reflection performance. In particular, a proper handling of geometry parameters may lead to considerable broadening of the antenna bandwidth. For the sake of computational efficiency, the adjustment of geometry parameters is carried out using surrogate-based optimization methods exploiting coarse-discretization EM simulations as the underlying low-fidelity antenna model. Additionally, suitably defined penalty function allows us to precisely control the maximum in-band reflection so that sufficient margin to accommodate possible manufacturing tolerances can be achieved. The optimized designs of the two antenna structures considered in this work exhibit over 1.75 GHz (>31%) and 2.15 GHz (>38%) bandwidth, respectively, for the center frequency of 5.6 GHz. Simulation results are validated using measurements of the fabricated prototypes. Comparison with state-of-the-art designs is also provided.

Original language	English
Pages (from-to)	653-659
Number of pages	7
Journal	International Journal of RF and Microwave Computer-Aided Engineering
Volume	26
Issue number	8
DOIs	https://doi.org/10.1002/mmce.21021
Publication status	Published - 1 Oct 2016

Bibliographical note

Funding Information:
The authors would like to thank Computer Simulation Technology AG, Darmstadt, Germany, for making CST Microwave Studio available. This work is partially supported by the Icelandic Centre for Research (RANNIS) Grants 141272051, 163299051 and by National Science Centre of Poland Grant 2014/15/B/ST7/04683.

Publisher Copyright:
© 2016 Wiley Periodicals, Inc.

Other keywords

bandwidth enhancement
EM-simulation-driven design
planar antennas
surrogate-based optimization

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10.1002/mmce.21021

Cite this

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title = "Precise control of reflection response in bandwidth-enhanced planar antennas",

abstract = "In this work, the issues of bandwidth enhancement of planar antennas and the relevance of precise and automated response control through numerical optimization have been investigated. Using an example of a planar antenna with parasitic radiator we illustrate possible effects of even minor modifications of the antenna geometry (here, applied to the ground plane) on its reflection performance. In particular, a proper handling of geometry parameters may lead to considerable broadening of the antenna bandwidth. For the sake of computational efficiency, the adjustment of geometry parameters is carried out using surrogate-based optimization methods exploiting coarse-discretization EM simulations as the underlying low-fidelity antenna model. Additionally, suitably defined penalty function allows us to precisely control the maximum in-band reflection so that sufficient margin to accommodate possible manufacturing tolerances can be achieved. The optimized designs of the two antenna structures considered in this work exhibit over 1.75 GHz (>31%) and 2.15 GHz (>38%) bandwidth, respectively, for the center frequency of 5.6 GHz. Simulation results are validated using measurements of the fabricated prototypes. Comparison with state-of-the-art designs is also provided.",

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N2 - In this work, the issues of bandwidth enhancement of planar antennas and the relevance of precise and automated response control through numerical optimization have been investigated. Using an example of a planar antenna with parasitic radiator we illustrate possible effects of even minor modifications of the antenna geometry (here, applied to the ground plane) on its reflection performance. In particular, a proper handling of geometry parameters may lead to considerable broadening of the antenna bandwidth. For the sake of computational efficiency, the adjustment of geometry parameters is carried out using surrogate-based optimization methods exploiting coarse-discretization EM simulations as the underlying low-fidelity antenna model. Additionally, suitably defined penalty function allows us to precisely control the maximum in-band reflection so that sufficient margin to accommodate possible manufacturing tolerances can be achieved. The optimized designs of the two antenna structures considered in this work exhibit over 1.75 GHz (>31%) and 2.15 GHz (>38%) bandwidth, respectively, for the center frequency of 5.6 GHz. Simulation results are validated using measurements of the fabricated prototypes. Comparison with state-of-the-art designs is also provided.

AB - In this work, the issues of bandwidth enhancement of planar antennas and the relevance of precise and automated response control through numerical optimization have been investigated. Using an example of a planar antenna with parasitic radiator we illustrate possible effects of even minor modifications of the antenna geometry (here, applied to the ground plane) on its reflection performance. In particular, a proper handling of geometry parameters may lead to considerable broadening of the antenna bandwidth. For the sake of computational efficiency, the adjustment of geometry parameters is carried out using surrogate-based optimization methods exploiting coarse-discretization EM simulations as the underlying low-fidelity antenna model. Additionally, suitably defined penalty function allows us to precisely control the maximum in-band reflection so that sufficient margin to accommodate possible manufacturing tolerances can be achieved. The optimized designs of the two antenna structures considered in this work exhibit over 1.75 GHz (>31%) and 2.15 GHz (>38%) bandwidth, respectively, for the center frequency of 5.6 GHz. Simulation results are validated using measurements of the fabricated prototypes. Comparison with state-of-the-art designs is also provided.

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Precise control of reflection response in bandwidth-enhanced planar antennas

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Bibliographical note

Other keywords

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