This study concerns how to model x-ray transmittance, exp ( -- ∫ μa(r, E) dr), of the object using a small number of energy-dependent bases, which plays an important role for estimating basis line-integrals in photon counting detector (PCD)-based computed tomography (CT). Recently, we found that low-order polynomials can model the smooth x-ray transmittance, i.e. object without contrast agents, with sufficient accuracy, and developed a computationally efficient three-step estimator. The algorithm estimates the polynomial coefficients in the first step, estimates the basis line-integrals in the second step, and corrects for bias in the third step. We showed that the three-step estimator was ~1,500 times faster than conventional maximum likelihood (ML) estimator while it provided comparable bias and noise. The three-step estimator was derived based on the modeling of x-ray transmittance; thus, the accurate modeling of x-ray transmittance is an important issue. For this purpose, we introduce a modeling of the x-ray transmittance via dictionary learning approach. We show that the relative modeling error of dictionary learning-based approach is smaller than that of the low-order polynomials.
[1]
K. Taguchi,et al.
Estimation of Basis Line-Integrals in a Spectral Distortion-Modeled Photon Counting Detector Using Low-Order Polynomial Approximation of X-ray Transmittance
,
2017,
IEEE Transactions on Medical Imaging.
[2]
K. Taguchi,et al.
Vision 20/20: Single photon counting x-ray detectors in medical imaging.
,
2013,
Medical physics.
[3]
E. Roessl,et al.
K-edge imaging in x-ray computed tomography using multi-bin photon counting detectors
,
2007,
Physics in medicine and biology.
[4]
A. Bruckstein,et al.
K-SVD : An Algorithm for Designing of Overcomplete Dictionaries for Sparse Representation
,
2005
.
[5]
J. Schlomka,et al.
Experimental feasibility of multi-energy photon-counting K-edge imaging in pre-clinical computed tomography
,
2008,
Physics in medicine and biology.