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Adaptive millimeter-wave synthetic aperture imaging for compressive sampling of sparse scenes.
Abstract
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.
Type
Journal articlePermalink
https://hdl.handle.net/10161/13876Collections
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Show full item recordScholars@Duke
David J. Brady
Michael J. Fitzpatrick Distinguished Professor Emeritus of Photonics
David Brady leads the Duke Information Spaces Project (DISP). Historically, DISP has
focused on computational imaging systems, with particular emphasis on smart cameras
for security, consumer, transportation and broadcast applications. Currently DISP
focuses primarily on the use of artificial intelligence in camera arrays for interactive
broadcasting.
Henry Everitt
Adjunct Professor of Physics
Dr. Everitt is the Army's senior technologist (ST) for optical sciences, a senior
executive currently working for the Army Research Laboratory in Houston, TX. Through
his adjunct appointment in the Duke Physics Department, he leads an active experimental
research group in molecular physics, novel terahertz imaging, nanophotonics, and ultrafast
spectroscopy of wide bandage semiconductors with colleagues on campus and through
an international network of collaborators. Four principal research
Daniel L. Marks
Associate Research Professor in the Department of Electrical and Computer Engineering
This author no longer has a Scholars@Duke profile, so the information shown here reflects
their Duke status at the time this item was deposited.
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