High spatial sampling light-guide snapshot spectrometer

Wang, Ye; Pawłowski, M.; Tkaczyk, Tomasz S.

doi:10.1117/1.oe.56.8.081803

Cited by 15 publications

(8 citation statements)

References 37 publications

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“…Noteworthily, unlike previous passive multidimensional imagers 7,26,27 , our active optical mapper can readily tune the mapping relation tailored for a given application. Also, it allows a flexible switch between direct and compressed measurement upon demands.…”

Section: Resultsmentioning

confidence: 99%

“…In conventional multidimensional optical imaging systems, the range of applicability of an image mapper is fixed upon being fabricated. For example, image spectrometers use passive image mappers, such as custom-designed mirror facets 7,41 or a bundle of fibres 27 , to separate and redirect the incident image. Ideally, the spatial and spectral sampling rates are solely determined by the pixel resolution of the camera provided a full utilisation of camera pixels.…”

Section: Discussionmentioning

confidence: 99%

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Snapshot multidimensional photography through active optical mapping

et al. 2020

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Multidimensional photography can capture optical fields beyond the capability of conventional image sensors that measure only two-dimensional (2D) spatial distribution of light. By mapping a high-dimensional datacube of incident light onto a 2D image sensor, multidimensional photography resolves the scene along with other information dimensions, such as wavelength and time. However, the application of current multidimensional imagers is fundamentally restricted by their static optical architectures and measurement schemes—the mapping relation between the light datacube voxels and image sensor pixels is fixed. To overcome this limitation, we propose tunable multidimensional photography through active optical mapping. A high-resolution spatial light modulator, referred to as an active optical mapper, permutes and maps the light datacube voxels onto sensor pixels in an arbitrary and programmed manner. The resultant system can readily adapt the acquisition scheme to the scene, thereby maximising the measurement flexibility. Through active optical mapping, we demonstrate our approach in two niche implementations: hyperspectral imaging and ultrafast imaging.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Snapshot multidimensional photography through active optical mapping

et al. 2020

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“…More recently, the same group reported using Lenslet array based tunable snapshot imaging spectrometry (LATIS) for high resolution fluorescence imaging with reported resolutions of 200x200 at 27 spectral channels and integration time of less than a second [13]. Other recently reported in-vivo systems include 4D snapshot hyperspectral video-endoscope [41], fiber-based prototype imaging spectrometer for oxygen saturation measurements [14] and Lyot filters based multispectral imagers [42].…”

Section: Survey Of Current Systems Suitable For Dynamic Imagingmentioning

confidence: 99%

“…Finding combinations of few spectral bands that are sufficient for lesion identification, would allow for simultaneous acquisition using the latest advances in fast scanning and high spatial resolution non-scanning imaging [13][14][15][16][17]. Overall, our studies offer several unbiased quantitative strategies as to how to limit the number of acquisition wavelengths while recognizing the target tissue with high accuracy.…”

Section: Introductionmentioning

confidence: 99%

Optimization of wavelength selection for multispectral image acquisition: a case study of atrial ablation lesions

Asfour

Guan

Muselimyan

et al. 2018

Biomed. Opt. Express

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Abstract:In vivo autofluorescence hyperspectral imaging of moving objects can be challenging due to motion artifacts and to the limited amount of acquired photons. To address both limitations, we selectively reduced the number of spectral bands while maintaining accurate target identification. Several downsampling approaches were applied to data obtained from the atrial tissue of adult pigs with sites of radiofrequency ablation lesions. Standard image qualifiers such as the mean square error, the peak signal-to-noise ratio, the structural similarity index map, and an accuracy index of lesion component images were used to quantify the effects of spectral binning, an increased spectral distance between individual bands, as well as random combinations of spectral bands. Results point to several quantitative strategies for deriving combinations of a small number of spectral bands that can successfully detect target tissue. Insights from our studies can be applied to a wide range of applications.

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“…Snapshot imaging spectrometers can be mainly classified into two categories—direct imaging and computational imaging [ 14 , 15 , 16 ]. The most typical direct imaging systems include integration-field spectroscopy (IFS) [ 17 , 18 ], the multispectral sagnac interferometer (MSI) [ 19 ], the image mapping spectrometer (IMS) [ 20 , 21 ], and the image replicating imaging spectrometer (IRIS) [ 22 , 23 ]. These systems have the advantage of possessing simple data reconstruction algorithms, which need less computational loads and thus can help to display and analyze spatial and spectral information at high frame rates [ 24 ].…”

Section: Introductionmentioning

confidence: 99%

Snapshot Imaging Spectrometer Based on Pixel-Level Filter Array (PFA)

Xie

Liu

et al. 2021

Sensors

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Snapshot spectral imaging technology plays an important role in many fields. However, most existing snapshot imaging spectrometers have the shortcomings of a large volume or heavy computational burden. In this paper, we present a novel snapshot imaging spectrometer based on the pixel-level filter array (PFA), which can simultaneously obtain both spectral and spatial information. The system is composed of a fore-optics, a PFA, a relay lens, and a monochromatic sensor. The incoming light first forms an intermediate image on the PFA through the fore-optics. Then, the relay lens reimages the spectral images on the PFA onto the monochromatic sensor. Through the use of the PFA, we can capture a three-dimensional (spatial coordinates and wavelength) datacube in a single exposure. Compared with existing technologies, our system possesses the advantages of a simple implementation, low cost, compact structure, and high energy efficiency by removing stacked dispersive or interferometric elements. Moreover, the characteristic of the direct imaging mode ensures the low computational burden of the system, thus shortening the imaging time. The principle and design of the system are described in detail. An experimental prototype is built and field experiments are carried out to verify the feasibility of the proposed scheme.

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High spatial sampling light-guide snapshot spectrometer

Cited by 15 publications

References 37 publications

Snapshot multidimensional photography through active optical mapping

Snapshot multidimensional photography through active optical mapping

Optimization of wavelength selection for multispectral image acquisition: a case study of atrial ablation lesions

Snapshot Imaging Spectrometer Based on Pixel-Level Filter Array (PFA)

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