Lateral migration radiography: a new x-ray backscatter imaging technique

Jacobs, Alan M.; Dugan, Edward T.; Brygoo, S.; Ekdahl, Dan; Houssay, Laurent; Su, Zhong

doi:10.1117/12.451613

Cited by 10 publications

(3 citation statements)

References 3 publications

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“…US researchers have recently developed a vehicle-mounted system, Lateral Migration X-ray Tomography, [19][20][21] which utilizes information from single and multiple scattered photons to image buried landmines. The approach used in this system is to scan a focused beam over the target area in order to render a spatially registered image.…”

Section: X-ray Backscatter Imagingmentioning

confidence: 99%

Defence R&D Canada research on nuclear methods of landmine detection

McFee

Faust

2003

SPIE Proceedings

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Defence R&D Canada (DRDC) has an active research and development program on detection of landmines using nuclear methods. They are intended for confirmation by detection of characteristic radiation or imaging of back scattered intensity distributions. Both vehicle-mounted and person-portable systems are being developed.Research on thermal neutron analysis (TNA) was initiated in 1994 to provide a confirmation detector for the DRDC developed multisensor, teleoperated, vehicle-mounted, landmine detection system. A version is now commercially available and four units have been fielded by the Canadian Land Forces. A prototype next generation TNA, which uses an electronic neutron generator as a source, has been constructed. Preliminary tests have shown improved performance. Research is now ongoing to investigate the addition of a fast neutron analysis capability to the next generation TNA. Characterization studies and software improvements are being conducted. Related research is investigating whether fast inorganic scintillator materials can provide an improvement in energy resolution.For person-portable applications, both neutron and photon irradiation processes are being investigated. A prototype landmine detector based on neutron moderation imaging has been completed and preliminary images of antipersonnel mine simulants obtained. It consists of a novel thermal neutron imaging system, a unique neutron source to uniformly irradiate the underlying ground and hardware and software for image generation and enhancement. Simulations show that it should provide a significant improvement over non-imaging neutron backscatter systems. X-ray backscatter imaging research is concentrating on non-collimated approaches to enable it to be person-portable. One such method, coded aperture imaging, is being investigated and extensive simulations using Geant4 have demonstrated its merits. Initial joint experiments with UC San Diego, using their HEXIS detector, have been conducted.

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Section: X-ray Backscatter Imagingmentioning

confidence: 99%

Defence R&D Canada research on nuclear methods of landmine detection

McFee

Faust

2003

SPIE Proceedings

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“…Lateral migration radiography (LMR), a type of backscatter x-ray radiography based upon selective detection of scatter field velocity components, was first applied at the University of Florida (UF) to the detection of buried land mines [1][2][3][4][5][6][7][8][9][10] . The resulting images were stunning in their definitive detail.…”

Section: Introductionmentioning

confidence: 99%

Detection of defects in foam thermal insulation using lateral migration backscatter x-ray radiography

et al. 2004

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A new Compton x-ray backscatter imaging technique called lateral migration radiography (LMR) has been successfully applied to the detection of voids and delaminations in the foam thermal insulation used on the shuttle external tank. LMR employs detection of selected scatter field velocity components, by using specially designed detectors and detector collimators, to achieve high image contrast.LMR is based on image contrast generated by migration of probe x-ray radiation in directions transverse to the illumination radiation beam. Because LMR is sensitive to electron density variations in these directions, thin, but large density variations, such as cracks and delaminations, generate signal-to-background ratios sufficient to produce images of features which are not even detectable in the usually interrogated thin dimension.The examined foam thermal insulation test panels consist of aluminum plates onto which the sprayed-on foam insulation (SOFI) is applied. Some of the test panels include structural features bolted to the base plate. The SOFI was layed down over the base plate and structure with a thickness varying from a few tens of mm up to a few hundred mm. The test panels included voids and simulated delaminations in the SOFI ranging in cross-sectional size from 6 x 6 mm to 50 x 50 mm. High quality images were acquired using pixels of 2 to 3 mm and irradiation times of as low as 0.05 s per pixel.

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“…The purpose of this investigation is to present and explain the different approaches that have been taken to develop a Modulation Transfer Function adapted to the Radiography by Selective Detection RSD imaging system [1][2][3][4][5][6][7][8][9][10][11][12] for the purpose of defining a process to measure system response by evaluating the image quality. Figure 1 shows a picture of the RSD system in which an X-ray tube is at a center of four detectors.…”

Section: Introductionmentioning

confidence: 99%

An adapted modulation transfer function for x-ray backscatter radiography by selective detection

et al. 2007

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The Modulation Transfer Function (MTF) is a quantitative function based on frequency resolution that characterizes imaging system performance. In this study, a new MTF methodology is investigated for application to Radiography by Selective Detection (RSD), an enhanced single-side x-ray Compton backscatter imaging (CBI) technique which detects selected scatter components. The RSD imaging modality is a unique type of real-time radiography that uses a set of fin and sleeve collimators to preferentially select different components of the x-ray backscattered field. Radiography by selective detection has performed successfully in different non-destructive evaluation (NDE) applications. A customized RSD imaging system was built at the University of Florida for inspection of the space shuttle external tank spray-on foam insulation (SOFI). The x-ray backscatter RSD imaging system has been successfully used for crack and corrosion detection in a variety of materials. The conventional transmission x-ray image quality characterization tools do not apply for RSD because of the different physical process involved. Thus, the main objective of this project is to provide an adapted tool for dynamic evaluation of RSD system image quality. For this purpose, an analytical model of the RSD imaging system response is developed and supported. Two approaches are taken for the MTF calculations: one using the Fourier Transform of a line spread function and the other one using a sine function pattern. Calibration and test targets are then designed according to this proposed model. A customized Matlab code using image contrast and digital curve recognition is developed to support the experimental data and provide the Modulation Transfer Functions for RSD.

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Lateral migration radiography: a new x-ray backscatter imaging technique

Cited by 10 publications

References 3 publications

Defence R&D Canada research on nuclear methods of landmine detection

Defence R&D Canada research on nuclear methods of landmine detection

Detection of defects in foam thermal insulation using lateral migration backscatter x-ray radiography

An adapted modulation transfer function for x-ray backscatter radiography by selective detection

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