Three-Dimensional Near-Field Microwave Holography for Tissue Imaging

Three-Dimensional Near-Field Microwave Holography for Tissue Imaging

This paper reports the progress toward a fast and reliable microwave imaging setup for tissue imaging exploiting near-field holographic reconstruction. The setup consists of two wideband TEM horn antennas aligned along each other’s boresight and performing a rectangular aperture raster scan. The tis...

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Main Authors: Reza K. Amineh, Ali Khalatpour, Haohan Xu, Yona Baskharoun, Natalia K. Nikolova
Format: Article
Language:English
Published: Hindawi Limited 2012-01-01
Series:International Journal of Biomedical Imaging
Online Access:http://dx.doi.org/10.1155/2012/291494
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spelling doaj-6c04325768b040feae402f4436d727d52020-11-24T22:08:33ZengHindawi LimitedInternational Journal of Biomedical Imaging1687-41881687-41962012-01-01201210.1155/2012/291494291494Three-Dimensional Near-Field Microwave Holography for Tissue ImagingReza K. Amineh0Ali Khalatpour1Haohan Xu2Yona Baskharoun3Natalia K. Nikolova4Department of Electrical and Computer Engineering, McMaster University, Hamilton, ON, L8S 4K1, CanadaDepartment of Electrical and Computer Engineering, McMaster University, Hamilton, ON, L8S 4K1, CanadaDepartment of Electrical and Computer Engineering, McMaster University, Hamilton, ON, L8S 4K1, CanadaDepartment of Electrical and Computer Engineering, McMaster University, Hamilton, ON, L8S 4K1, CanadaDepartment of Electrical and Computer Engineering, McMaster University, Hamilton, ON, L8S 4K1, CanadaThis paper reports the progress toward a fast and reliable microwave imaging setup for tissue imaging exploiting near-field holographic reconstruction. The setup consists of two wideband TEM horn antennas aligned along each other’s boresight and performing a rectangular aperture raster scan. The tissue sensing is performed without coupling liquids. At each scanning position, wideband data is acquired. Then, novel holographic imaging algorithms are implemented to provide three-dimensional images of the inspected domain. In these new algorithms, the required incident field and Green’s function are obtained from numerical simulations. They replace the plane (or spherical) wave assumption in the previous holographic methods and enable accurate near-field imaging results. Here, we prove that both the incident field and Green’s function can be obtained from a single numerical simulation. This eliminates the need for optimization-based deblurring which was previously employed to remove the effect of realistic non-point-wise antennas.http://dx.doi.org/10.1155/2012/291494
collection DOAJ
language English
format Article
sources DOAJ
author Reza K. Amineh
Ali Khalatpour
Haohan Xu
Yona Baskharoun
Natalia K. Nikolova
spellingShingle Reza K. Amineh
Ali Khalatpour
Haohan Xu
Yona Baskharoun
Natalia K. Nikolova
Three-Dimensional Near-Field Microwave Holography for Tissue Imaging
International Journal of Biomedical Imaging
author_facet Reza K. Amineh
Ali Khalatpour
Haohan Xu
Yona Baskharoun
Natalia K. Nikolova
author_sort Reza K. Amineh
title Three-Dimensional Near-Field Microwave Holography for Tissue Imaging
title_short Three-Dimensional Near-Field Microwave Holography for Tissue Imaging
title_full Three-Dimensional Near-Field Microwave Holography for Tissue Imaging
title_fullStr Three-Dimensional Near-Field Microwave Holography for Tissue Imaging
title_full_unstemmed Three-Dimensional Near-Field Microwave Holography for Tissue Imaging
title_sort three-dimensional near-field microwave holography for tissue imaging
publisher Hindawi Limited
series International Journal of Biomedical Imaging
issn 1687-4188
1687-4196
publishDate 2012-01-01
description This paper reports the progress toward a fast and reliable microwave imaging setup for tissue imaging exploiting near-field holographic reconstruction. The setup consists of two wideband TEM horn antennas aligned along each other’s boresight and performing a rectangular aperture raster scan. The tissue sensing is performed without coupling liquids. At each scanning position, wideband data is acquired. Then, novel holographic imaging algorithms are implemented to provide three-dimensional images of the inspected domain. In these new algorithms, the required incident field and Green’s function are obtained from numerical simulations. They replace the plane (or spherical) wave assumption in the previous holographic methods and enable accurate near-field imaging results. Here, we prove that both the incident field and Green’s function can be obtained from a single numerical simulation. This eliminates the need for optimization-based deblurring which was previously employed to remove the effect of realistic non-point-wise antennas.
url http://dx.doi.org/10.1155/2012/291494
work_keys_str_mv AT rezakamineh threedimensionalnearfieldmicrowaveholographyfortissueimaging
AT alikhalatpour threedimensionalnearfieldmicrowaveholographyfortissueimaging
AT haohanxu threedimensionalnearfieldmicrowaveholographyfortissueimaging
AT yonabaskharoun threedimensionalnearfieldmicrowaveholographyfortissueimaging
AT nataliaknikolova threedimensionalnearfieldmicrowaveholographyfortissueimaging
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