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Bibliographic Details
Main Authors: Guerrero, Patricio, Bellens, Simon, Santander, Ricardo, Dewulf, Wim
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2310.09567
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author Guerrero, Patricio
Bellens, Simon
Santander, Ricardo
Dewulf, Wim
author_facet Guerrero, Patricio
Bellens, Simon
Santander, Ricardo
Dewulf, Wim
contents This work is concerned with fan- and cone-beam computed tomography with circular source trajectory, where the reconstruction inverse problem requires an accurate knowledge of source, detector and rotational axis relative positions and orientations. We address this additional inverse problem as a preceding step of the reconstruction process directly from the acquired projections. In the cone-beam case, we present a method that estimates both the detector shift (orthogonal to both focal and rotational axes) and the in-plane detector rotation (over the focal axis) based on the variable projection optimization approach. In addition and for the fan-beam case, two new strategies with low computational cost are presented to estimate the detector shift based on a fan-beam symmetry condition. The methods are validated with simulated and experimental industrial tomographic data with code examples available for both fan- and cone-beam geometries.
format Preprint
id arxiv_https___arxiv_org_abs_2310_09567
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Automatic and Computationally Efficient Alignment in Fan- and Cone-beam Tomography
Guerrero, Patricio
Bellens, Simon
Santander, Ricardo
Dewulf, Wim
Numerical Analysis
This work is concerned with fan- and cone-beam computed tomography with circular source trajectory, where the reconstruction inverse problem requires an accurate knowledge of source, detector and rotational axis relative positions and orientations. We address this additional inverse problem as a preceding step of the reconstruction process directly from the acquired projections. In the cone-beam case, we present a method that estimates both the detector shift (orthogonal to both focal and rotational axes) and the in-plane detector rotation (over the focal axis) based on the variable projection optimization approach. In addition and for the fan-beam case, two new strategies with low computational cost are presented to estimate the detector shift based on a fan-beam symmetry condition. The methods are validated with simulated and experimental industrial tomographic data with code examples available for both fan- and cone-beam geometries.
title Automatic and Computationally Efficient Alignment in Fan- and Cone-beam Tomography
topic Numerical Analysis
url https://arxiv.org/abs/2310.09567