Multigrid Reconstruction Technique for X-ray Fluorescence Computed Tomography

Bo Gao, L. Van Hoorebeke, L. Vincze, M. Boone
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Abstract

X-ray Fluorescence Computed Tomography (XFCT) is an imaging modality aiming at mapping the elemental distribution inside the sample non-invasively. However, the self-absorption effect associated with XFCT makes the accurate reconstruction challenging. To solve this issue, reconstruction algorithms that compensates this effect have been proposed. Due to the computational complexity, almost all algorithms proposed for XFCT reconstruction have modelled XFCT in a 2D plane, which is an approximation only accurate in limited cases. In this manuscript, the limitation of modelling XFCT in a 2D plane is demonstrated. Then, an effective method for the acceleration of XFCT reconstruction in the 3D space, namely multigrid XFCT reconstruction, is proposed. Specifically, multigrid refers to the different discretization grids, on which the elemental distributions and the attenuation coefficients at the energies of fluorescence X-rays are reconstructed. Through test, it can be shown that an accurate density distribution could be obtained even if the attenuation coefficients have been reconstructed on a coarser grid. As the multigrid reconstruction strategy is independent of the methodology behind the reconstruction algorithms, it could be used to accelerate all XFCT reconstruction algorithms that simultaneously reconstruct the elemental density and the attenuation coefficients at the energies of fluorescence X-rays.
x射线荧光计算机断层扫描的多网格重建技术
x射线荧光计算机断层扫描(XFCT)是一种旨在无创性地绘制样品内部元素分布的成像方式。然而,与XFCT相关的自吸收效应使得精确重建具有挑战性。为了解决这一问题,已经提出了补偿这一影响的重建算法。由于计算的复杂性,几乎所有提出的XFCT重建算法都是在二维平面上对XFCT进行建模,这种近似只在有限的情况下是准确的。在这篇手稿中,XFCT在二维平面上建模的局限性被证明。然后,提出了一种在三维空间加速XFCT重建的有效方法,即多网格XFCT重建。具体来说,多重网格是指在不同的离散网格上重建荧光x射线能量处的元素分布和衰减系数。试验表明,即使在较粗的网格上重构衰减系数,也能得到较精确的密度分布。由于多重网格重建策略独立于重建算法背后的方法,它可以用来加速所有同时重建荧光x射线能量下元素密度和衰减系数的XFCT重建算法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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