KRISM—Krylov Subspace-based Optical Computing of Hyperspectral Images

Saragadam, Vishwanath; Sankaranarayanan, Aswin C.

doi:10.1145/3345553

Cited by 19 publications

(12 citation statements)

References 51 publications

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“…This result was first explored in [7] and [9] where they stated that a slit trades off spatial and spectral resolution. Our paper builds on their results by providing a concise expression for the tradeoff.…”

Section: Resultsmentioning

confidence: 99%

“…Hyperspectral imagers. Apart from programmable spectral filtering, several hyperspectral imaging architectures [8][9][10] rely on obtaining spectrally-modulated images. Our findings have a direct implication on such setups, as a key requirement of such setups is to capture high resolution images without sacrificing spectral resolution.…”

Section: Discussionmentioning

confidence: 99%

“…The analysis in this paper is for the optical setup shown in Fig. 1, commonly used in prior art for spectral filtering [4,[7][8][9]. The optical system consists of a series of lenses of focal length f , each subsequent pair separated by 2 f .…”

Section: Problem Settingmentioning

confidence: 99%

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On Space-spectrum Uncertainty Analysis for Coded Aperture Systems

Saragadam,

Sankaranarayanan

2019

Preprint

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We introduce and analyze the concept of space-spectrum uncertainty for certain commonly-used designs for spectrally programmable cameras. Our key finding states that, it is impossible to simultaneously capture high-resolution spatial images while programming the spectrum at high resolution. This phenomenon arises due to a Fourier relationship between the aperture used for obtaining spectrum and its corresponding diffraction blur in the (spatial) image. We show that the product of spatial and spectral standard deviations is lower bounded by λ 4πν 0 femto square-meters, where ν 0 is the density of groves in the diffraction grating and λ is the wavelength of light. Experiments with a lab prototype for simultaneously measuring spectrum and image validate our findings and its implication for spectral filtering.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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On Space-spectrum Uncertainty Analysis for Coded Aperture Systems

Saragadam,

Sankaranarayanan

2019

Preprint

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“…Some Matrix factorization-based methods considering the spectral basis and spatial structures have been proposed; for example, Chen et al [27] proposed a joint spatial-spectral resolution method with spectral matrix factorization and spatial sparsity constraints. The property that real-world HSI are locally low-rank is used to partition the hyperspectral image into patches and helps the optical computing of HSIs [28].…”

Section: Related Workmentioning

confidence: 99%

Hyperspectral Image Super-Resolution Based on Spatial Group Sparsity Regularization Unmixing

Peng

Jiang

et al. 2020

Applied Sciences

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A hyperspectral image (HSI) contains many narrow spectral channels, thus containing efficient information in the spectral domain. However, high spectral resolution usually leads to lower spatial resolution as a result of the limitations of sensors. Hyperspectral super-resolution aims to fuse a low spatial resolution HSI with a conventional high spatial resolution image, producing an HSI with high resolution in both the spectral and spatial dimensions. In this paper, we propose a spatial group sparsity regularization unmixing-based method for hyperspectral super-resolution. The hyperspectral image (HSI) is pre-clustered using an improved Simple Linear Iterative Clustering (SLIC) superpixel algorithm to make full use of the spatial information. A robust sparse hyperspectral unmixing method is then used to unmix the input images. Then, the endmembers extracted from the HSI and the abundances extracted from the conventional image are fused. This ensures that the method makes full use of the spatial structure and the spectra of the images. The proposed method is compared with several related methods on public HSI data sets. The results demonstrate that the proposed method has superior performance when compared to the existing state-of-the-art.

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“…Existing datasets mainly focus on the scalar or RGB intensity of scattered light, neglecting other physical properties of light such as its spectrum and polarization state [Baek et al 2018;Kadambi et al 2015;Saragadam and Sankaranarayanan 2019]. While neither is strictly necessary to produce images that are meant for human consumption, they are play an important role in applications that require a particularly high level of accuracy, such as predictive rendering.…”

Section: Introductionmentioning

confidence: 99%

Image-based acquisition and modeling of polarimetric reflectance

Baek

Zeltner

et al. 2020

ACM Trans. Graph.

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color albedos, captured in five wavelength ranges covering the visible spectrum. We demonstrate usage of our data-driven pBRDF model in a physically based renderer that accounts for polarized interreflection, and we investigate the relationship of polarization and material appearance, providing insights into the behavior of characteristic real-world pBRDFs. CCS Concepts: • Computing methodologies → Image and video acquisition; Reflectance modeling.

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KRISM—Krylov Subspace-based Optical Computing of Hyperspectral Images

Cited by 19 publications

References 51 publications

On Space-spectrum Uncertainty Analysis for Coded Aperture Systems

On Space-spectrum Uncertainty Analysis for Coded Aperture Systems

Hyperspectral Image Super-Resolution Based on Spatial Group Sparsity Regularization Unmixing

Image-based acquisition and modeling of polarimetric reflectance

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