Detection of explosives by differential hyperspectral imaging

Dubroca, Thierry; Brown, Gregory V.; Hummel, Rolf E.

doi:10.1117/1.oe.53.2.021112

Cited by 14 publications

(6 citation statements)

References 16 publications

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“…Because the underlying physics relies on electronic absorptions that are typically broad and indistinct, selectivity is not expected to be nearly as high as for vibrational spectroscopy. Despite these difficulties, differential hyperspectral imaging [81,82] under active illumination in the 200-500 nm range has been used to achieve a limit of detection (LOD) of 100 ng for TNT with selective ROCs [83].…”

Section: Ultraviolet-visiblementioning

confidence: 99%

Advances in explosives analysis—part II: photon and neutron methods

et al. 2015

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The number and capability of explosives detection and analysis methods have increased dramatically since publication of the Analytical and Bioanalytical Chemistry special issue devoted to Explosives Analysis [Moore DS, Goodpaster JV, Anal Bioanal Chem 395:245-246, 2009]. Here we review and critically evaluate the latest (the past five years) important advances in explosives detection, with details of the improvements over previous methods, and suggest possible avenues towards further advances in, e.g., stand-off distance, detection limit, selectivity, and penetration through camouflage or packaging. The review consists of two parts. Part I discussed methods based on animals, chemicals (including colorimetry, molecularly imprinted polymers, electrochemistry, and immunochemistry), ions (both ion-mobility spectrometry and mass spectrometry), and mechanical devices. This part, Part II, will review methods based on photons, from very energetic photons including X-rays and gamma rays down to the terahertz range, and neutrons.

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Section: Ultraviolet-visiblementioning

confidence: 99%

Advances in explosives analysis—part II: photon and neutron methods

et al. 2015

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“…Hyperspectral imaging has a wide range of applications, can perform fine classification and identification of material properties, and has the advantages of long-distance, non-contact, and non-destructive detection. However, in the current literature, there are few research results on the identification and detection of hazardous chemicals using a hyperspectral imaging technique [28][29][30][31]. In this study, we attempted to take advantage of these two disciplines to apply refined classification with a high spectral resolution to the identification of hazardous chemicals, so as to establish a certain theoretical framework and provide a new method for long-distance and non-contact detection of hazardous chemicals.…”

Section: Introductionmentioning

confidence: 99%

Identification of Typical Solid Hazardous Chemicals Based on Hyperspectral Imaging

et al. 2021

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The identification of hazardous chemicals based on hyperspectral imaging is an important emergent means for the prevention of explosion accidents and the early warning of secondary hazards. In this study, we used a combination of spectral curve matching based on full-waveform characteristics and spectral matching based on spectral characteristics to identify the hazardous chemicals, and proposed a method to quantitatively characterize the matching degree of the spectral curves of hazardous chemicals. The results showed that the four hazardous chemicals, sulfur, red phosphorus, potassium permanganate, and corn starch had bright colors, distinct spectral curve characteristics, and obvious changes in reflectivity, which were easy to identify. Moreover, the matching degree of their spectral curves was positively correlated with their reflectivity. However, the spectral characteristics of carbon powder, strontium nitrate, wheat starch, and magnesium–aluminum alloy powder were not obvious, with no obvious characteristic peaks or trends of change in reflectivity. Except for the reflectivity and the matching degree of the carbon powder being maintained at a low level, the reflectivity of the remaining three samples was relatively close, so that it was difficult to identify with the spectral curves alone, and color information should be considered for further identification.

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“…Thanks to this they can uncover information hidden inside the spectral response characteristics of a scene. This information has a huge potential to add value to a diverse range of real-life applications including remote sensing [1], food science [2], medical imaging [3], optical sorting [4], precision agriculture [5], security [6], forensics [7], colorimetry [8], ... Clearly, good spectral imaging performance will be needed to exploit this potential. However, a consideration of the diverse requirements introduced by moving the spectral cameras out of the lab and into the unique environments linked to these applications will also be essential: a spectral camera for the optical sorting application domain [4] will typically exhibit a need for extremely high frame rates to enable high scanning speeds, a need for high spectral resolution to maximize flexibility and sorting accuracy, and a need for high spatial resolution to track fine details.…”

Section: Introductionmentioning

confidence: 99%

A tiny VIS-NIR snapshot multispectral camera

et al. 2015

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Spectral imaging can reveal a lot of hidden details about the world around us, but is currently confined to laboratory environments due to the need for complex, costly and bulky cameras. Imec has developed a unique spectral sensor concept in which the spectral unit is monolithically integrated on top of a standard CMOS image sensor at wafer level, hence enabling the design of compact, low cost and high acquisition speed spectral cameras with a high design flexibility. This flexibility has previously been demonstrated by imec in the form of three spectral camera architectures: firstly a high spatial and spectral resolution scanning camera, secondly a multichannel snapshot multispectral camera and thirdly a per-pixel mosaic snapshot spectral camera. These snapshot spectral cameras sense an entire multispectral data cube at one discrete point in time, extending the domain of spectral imaging towards dynamic, video-rate applications. This paper describes the integration of our per-pixel mosaic snapshot spectral sensors inside a tiny, portable and extremely user-friendly camera. Our prototype demonstrator cameras can acquire multispectral image cubes, either of 272x512 pixels over 16 bands in the VIS (470-620nm) or of 217x409 pixels over 25 bands in the VNIR (600-900nm) at 170 cubes per second for normal machine vision illumination levels. The cameras themselves are extremely compact based on Ximea xiQ cameras, measuring only 26x26x30mm, and can be operated from a laptop-based USB3 connection, making them easily deployable in very diverse environments.

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Detection of explosives by differential hyperspectral imaging

Cited by 14 publications

References 16 publications

Advances in explosives analysis—part II: photon and neutron methods

Advances in explosives analysis—part II: photon and neutron methods

Identification of Typical Solid Hazardous Chemicals Based on Hyperspectral Imaging

A tiny VIS-NIR snapshot multispectral camera

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