Wangduo Xie, Richard Schoonhoven, Tristan van Leeuwen, Matthew B. Blaschko
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AC-IND: Sparse CT reconstruction based on attenuation coefficient estimation and implicit neural distribution
Computed tomography (CT) reconstruction plays a crucial role in industrial
nondestructive testing and medical diagnosis. Sparse view CT reconstruction
aims to reconstruct high-quality CT images while only using a small number of
projections, which helps to improve the detection speed of industrial assembly
lines and is also meaningful for reducing radiation in medical scenarios.
Sparse CT reconstruction methods based on implicit neural representations
(INRs) have recently shown promising performance, but still produce artifacts
because of the difficulty of obtaining useful prior information. In this work,
we incorporate a powerful prior: the total number of material categories of
objects. To utilize the prior, we design AC-IND, a self-supervised method based
on Attenuation Coefficient Estimation and Implicit Neural Distribution.
Specifically, our method first transforms the traditional INR from scalar
mapping to probability distribution mapping. Then we design a compact
attenuation coefficient estimator initialized with values from a rough
reconstruction and fast segmentation. Finally, our algorithm finishes the CT
reconstruction by jointly optimizing the estimator and the generated
distribution. Through experiments, we find that our method not only outperforms
the comparative methods in sparse CT reconstruction but also can automatically
generate semantic segmentation maps.