Resolution of the Frequency Diverse Metamaterial Aperture Imager

Okan Yurduseven; Mohammadreza F. Imani; Hayrettin  Odabasi; Jonah Gollub; Guy Lipworth; Alec  Rose; David Smith

doi:10.2528/PIER14113002

Resolution of the Frequency Diverse Metamaterial Aperture Imager

Okan Yurduseven, Mohammadreza F. Imani, Hayrettin Odabasi, Jonah Gollub, Guy Lipworth, Alec Rose, David Smith

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Abstract

The resolution of a frequency diverse compressive metamaterial aperture imager is investigated. The aperture consists of a parallel plate waveguide, in which an array of complementary, resonant metamaterial elements is patterned into one of the plates. Microwaves injected into the waveguide leak out through the resonant metamaterial elements, forming a spatially diverse waveform at the scene. As the frequency is scanned, the waveforms change, such that scene information can be encoded onto a set of frequency measurements. The compressive nature of the metamaterial imager enables image reconstruction from significantly reduced number of measurements. We characterize the resolution of this complex aperture by studying the simulated point spread function (PSF) computed using different image reconstruction techniques. We compare the imaging performance of the system with that expected from synthetic aperture radar (SAR) limits.

Original language	English
Pages (from-to)	97-107
Journal	Progress In Electromagnetics Research
Volume	150
DOIs	https://doi.org/10.2528/PIER14113002
Publication status	Published - 19 Jan 2015
Externally published	Yes

Keywords

RESOLUTION
Imaging techniques
Computational Imaging
RADAR

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Resolution of the Frequency Diverse Metamaterial Aperture Imager
Copyright 2015, EMW Publishing on behalf of The Electromagnetics Academy. This work is made available online in accordance with the publisher’s policies. Please refer to any applicable terms of use of the publisher.
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Cite this

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title = "Resolution of the Frequency Diverse Metamaterial Aperture Imager",

abstract = "The resolution of a frequency diverse compressive metamaterial aperture imager is investigated. The aperture consists of a parallel plate waveguide, in which an array of complementary, resonant metamaterial elements is patterned into one of the plates. Microwaves injected into the waveguide leak out through the resonant metamaterial elements, forming a spatially diverse waveform at the scene. As the frequency is scanned, the waveforms change, such that scene information can be encoded onto a set of frequency measurements. The compressive nature of the metamaterial imager enables image reconstruction from significantly reduced number of measurements. We characterize the resolution of this complex aperture by studying the simulated point spread function (PSF) computed using different image reconstruction techniques. We compare the imaging performance of the system with that expected from synthetic aperture radar (SAR) limits.",

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T1 - Resolution of the Frequency Diverse Metamaterial Aperture Imager

AU - Yurduseven, Okan

AU - Imani, Mohammadreza F.

AU - Odabasi, Hayrettin

AU - Gollub, Jonah

AU - Lipworth, Guy

AU - Rose, Alec

AU - Smith, David

PY - 2015/1/19

Y1 - 2015/1/19

N2 - The resolution of a frequency diverse compressive metamaterial aperture imager is investigated. The aperture consists of a parallel plate waveguide, in which an array of complementary, resonant metamaterial elements is patterned into one of the plates. Microwaves injected into the waveguide leak out through the resonant metamaterial elements, forming a spatially diverse waveform at the scene. As the frequency is scanned, the waveforms change, such that scene information can be encoded onto a set of frequency measurements. The compressive nature of the metamaterial imager enables image reconstruction from significantly reduced number of measurements. We characterize the resolution of this complex aperture by studying the simulated point spread function (PSF) computed using different image reconstruction techniques. We compare the imaging performance of the system with that expected from synthetic aperture radar (SAR) limits.

AB - The resolution of a frequency diverse compressive metamaterial aperture imager is investigated. The aperture consists of a parallel plate waveguide, in which an array of complementary, resonant metamaterial elements is patterned into one of the plates. Microwaves injected into the waveguide leak out through the resonant metamaterial elements, forming a spatially diverse waveform at the scene. As the frequency is scanned, the waveforms change, such that scene information can be encoded onto a set of frequency measurements. The compressive nature of the metamaterial imager enables image reconstruction from significantly reduced number of measurements. We characterize the resolution of this complex aperture by studying the simulated point spread function (PSF) computed using different image reconstruction techniques. We compare the imaging performance of the system with that expected from synthetic aperture radar (SAR) limits.

KW - RESOLUTION

KW - Imaging techniques

KW - Computational Imaging

KW - RADAR

U2 - 10.2528/PIER14113002

DO - 10.2528/PIER14113002

M3 - Article

VL - 150

SP - 97

EP - 107

JO - Progress In Electromagnetics Research

JF - Progress In Electromagnetics Research

SN - 1070-4698

ER -

Resolution of the Frequency Diverse Metamaterial Aperture Imager

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Keywords

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