David J. Brady scite author profile

We present a single disperser spectral imager that exploits recent theoretical work in the area of compressed sensing to achieve snapshot spectral imaging. An experimental prototype is used to capture the spatiospectral information of a scene that consists of two balls illuminated by different light sources. An iterative algorithm is used to reconstruct the data cube. The average spectral resolution is 3.6 nm per spectral channel. The accuracy of the instrument is demonstrated by comparison of the spectra acquired with the proposed system with the spectra acquired by a nonimaging reference spectrometer.

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Single-shot compressive spectral imaging with a dual-disperser architecture

Gehm¹,

John²,

Brady³

et al. 2007

Opt. Express

652

349

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This paper describes a single-shot spectral imaging approach based on the concept of compressive sensing. The primary features of the system design are two dispersive elements, arranged in opposition and surrounding a binary-valued aperture code. In contrast to thin-film approaches to spectral filtering, this structure results in easily-controllable, spatially-varying, spectral filter functions with narrow features. Measurement of the input scene through these filters is equivalent to projective measurement in the spectral domain, and hence can be treated with the compressive sensing frameworks recently developed by a number of groups. We present a reconstruction framework and demonstrate its application to experimental data.

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Metamaterial Apertures for Computational Imaging

Hunt

Driscoll

Mrozack

et al. 2013

Science

547

320

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By leveraging metamaterials and compressive imaging, a low-profile aperture capable of microwave imaging without lenses, moving parts, or phase shifters is demonstrated. This designer aperture allows image compression to be performed on the physical hardware layer rather than in the postprocessing stage, thus averting the detector, storage, and transmission costs associated with full diffraction-limited sampling of a scene. A guided-wave metamaterial aperture is used to perform compressive image reconstruction at 10 frames per second of two-dimensional (range and angle) sparse still and video scenes at K-band (18 to 26 gigahertz) frequencies, using frequency diversity to avoid mechanical scanning. Image acquisition is accomplished with a 40:1 compression ratio.

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Coded aperture compressive temporal imaging

et al. 2013

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Compressive Holography

Brady¹,

Choi²,

Marks³

et al. 2009

Opt. Express

493

295

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David J. Brady

Single disperser design for coded aperture snapshot spectral imaging

Single-shot compressive spectral imaging with a dual-disperser architecture

Metamaterial Apertures for Computational Imaging

Coded aperture compressive temporal imaging

Compressive Holography

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