Abstract
The reconstruction problem in in-line X-ray Phase-Contrast Tomography is usually approached by solving two independent linearized sub-problems: phase retrieval and tomographic reconstruction. Both problems are often ill-posed and require the use of regularization techniques that lead to artifacts in the reconstructed image. We present a novel reconstruction approach that solves two coupled linear problems algebraically. Our approach is based on the assumption that the frequency space of the tomogram can be divided into bands that are accurately recovered and bands that are undefined by the observations. This results in an underdetermined linear system of equations. We investigate how this system can be solved using three different algebraic reconstruction algorithms based on Total Variation minimization. These algorithms are compared using both simulated and experimental data. Our results demonstrate that in many cases the proposed algebraic algorithms yield a significantly improved accuracy over the conventional L2-regularized closed-form solution. This work demonstrates that algebraic algorithms may become an important tool in applications where the acquisition time and the delivered radiation dose must be minimized.
Highlights
Quantitative X-ray Phase-Contrast Tomography (X-ray PCT) requires three-dimensional image reconstruction from a series of two-dimensional in-line phase-contrast images acquired under various angles
By combining (1) and (9) we can rewrite the central slice theorem for what we call Phase Retrieval Tomography (PRT), i.e. phase retrieval combined with tomographic reconstruction: f(w cos θ, w sin θ )
The results of reconstructions for the simulated data (Fig. 3) demonstrate that a TV minimization approach can yield a nearly flawless tomographic reconstruction based on a single distance X-ray PCT data
Summary
Quantitative X-ray Phase-Contrast Tomography (X-ray PCT) requires three-dimensional image reconstruction from a series of two-dimensional in-line phase-contrast images acquired under various angles. We believe that a more accurate reconstruction approach can be designed by combining phase retrieval and tomographic reconstruction into a single underdetermined linear problem. This assumption is based on the fact that tomographic projections of the object are in general not independent from each other. The projection data shows a low rate of innovation, which implies that a limited number of projections suffices for exact reconstruction [5] These facts lead us to a conclusion that the accuracy of phase retrieval of a single tomographic projection can benefit from the redundancy contained in the complete tomographic dataset.
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