Open AccessAdaptive millimeter-wave synthetic aperture imaging for compressive sampling of sparse scenes
Author(s) -
Alex Mrozack,
Martin S. Heimbeck,
Daniel L. Marks,
Jonathan T. Richard,
Henry O. Everitt,
David J. Brady
Publication year - 2014
Publication title -
optics express
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.394
H-Index - 271
ISSN - 1094-4087
DOI - 10.1364/oe.22.013515
Subject(s) - optics , raster scan , synthetic aperture radar , detector , compressed sensing , inverse synthetic aperture radar , radar imaging , sampling (signal processing) , sparse array , radar , aperture (computer memory) , computer science , translation (biology) , raster graphics , extremely high frequency , inverse problem , wavelength , scattering , inverse scattering problem , algorithm , physics , acoustics , computer vision , mathematics , telecommunications , mathematical analysis , biochemistry , chemistry , messenger rna , gene
We apply adaptive sensing techniques to the problem of locating sparse metallic scatterers using high-resolution, frequency modulated continuous wave W-band RADAR. Using a single detector, a frequency stepped source, and a lateral translation stage, inverse synthetic aperture RADAR reconstruction techniques are used to search for one or two wire scatterers within a specified range, while an adaptive algorithm determined successive sampling locations. The two-dimensional location of each scatterer is thereby identified with sub-wavelength accuracy in as few as 1/4 the number of lateral steps required for a simple raster scan. The implications of applying this approach to more complex scattering geometries are explored in light of the various assumptions made.
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