Samantha J Alloo1, David M Paganin2, Kaye S Morgan2, Marcus J Kitchen2, Andrew W Stevenson3, Sheridan C Mayo4, Heyang T Li5, Ben M Kennedy6, Anton Maksimenko3, Joshua C Bowden4, Konstantin M Pavlov1,2,7. 1. University of Canterbury, School of Physical and Chemical Sciences, Christchurch, New Zealand. 2. Monash University, School of Physics and Astronomy, Melbourne, Victoria, Australia. 3. ANSTO, Australian Synchrotron, Clayton, Victoria, Australia. 4. Commonwealth Scientific and Industrial Research Organisation, Clayton, Victoria, Australia. 5. University of Canterbury, School of Mathematics and Statistics, Christchurch, New Zealand. 6. University of Canterbury, School of Earth and Environment, Christchurch, New Zealand. 7. University of New England, Armidale, New South Wales, Australia.
Abstract
Purpose: We investigate how an intrinsic speckle tracking approach to speckle-based x-ray imaging is used to extract an object's effective dark-field (DF) signal, which is capable of providing object information in three dimensions. Approach: The effective DF signal was extracted using a Fokker-Planck type formalism, which models the deformations of illuminating reference beam speckles due to both coherent and diffusive scatter from the sample. Here, we assumed that (a) small-angle scattering fans at the exit surface of the sample are rotationally symmetric and (b) the object has both attenuating and refractive properties. The associated inverse problem of extracting the effective DF signal was numerically stabilized using a "weighted determinants" approach. Results: Effective DF projection images, as well as the DF tomographic reconstructions of the wood sample, are presented. DF tomography was performed using a filtered back projection reconstruction algorithm. The DF tomographic reconstructions of the wood sample provided complementary, and otherwise inaccessible, information to augment the phase contrast reconstructions, which were also computed. Conclusions: An intrinsic speckle tracking approach to speckle-based imaging can tomographically reconstruct an object's DF signal at a low sample exposure and with a simple experimental setup. The obtained DF reconstructions have an image quality comparable to alternative x-ray DF techniques.
Purpose: We investigate how an intrinsic speckle tracking approach to speckle-based x-ray imaging is used to extract an object's effective dark-field (DF) signal, which is capable of providing object information in three dimensions. Approach: The effective DF signal was extracted using a Fokker-Planck type formalism, which models the deformations of illuminating reference beam speckles due to both coherent and diffusive scatter from the sample. Here, we assumed that (a) small-angle scattering fans at the exit surface of the sample are rotationally symmetric and (b) the object has both attenuating and refractive properties. The associated inverse problem of extracting the effective DF signal was numerically stabilized using a "weighted determinants" approach. Results: Effective DF projection images, as well as the DF tomographic reconstructions of the wood sample, are presented. DF tomography was performed using a filtered back projection reconstruction algorithm. The DF tomographic reconstructions of the wood sample provided complementary, and otherwise inaccessible, information to augment the phase contrast reconstructions, which were also computed. Conclusions: An intrinsic speckle tracking approach to speckle-based imaging can tomographically reconstruct an object's DF signal at a low sample exposure and with a simple experimental setup. The obtained DF reconstructions have an image quality comparable to alternative x-ray DF techniques.
Authors: T E Gureyev; A W Stevenson; D M Paganin; T Weitkamp; A Snigirev; I Snigireva; S W Wilkins Journal: J Synchrotron Radiat Date: 2002-04-25 Impact factor: 2.616
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Authors: Marcus J Kitchen; David M Paganin; Kentaro Uesugi; Beth J Allison; Robert A Lewis; Stuart B Hooper; Konstantin M Pavlov Journal: Phys Med Biol Date: 2011-01-06 Impact factor: 3.609
Authors: Timm Weitkamp; Ana Diaz; Christian David; Franz Pfeiffer; Marco Stampanoni; Peter Cloetens; Eric Ziegler Journal: Opt Express Date: 2005-08-08 Impact factor: 3.894
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