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Bibliographic Details
Main Authors: Konik, Anastasia, Desbat, Laurent
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2505.08805
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author Konik, Anastasia
Desbat, Laurent
author_facet Konik, Anastasia
Desbat, Laurent
contents In tomography, range conditions or data consistency conditions (DCCs) on functions have proven useful for geometric self-calibration, which involves identifying geometric parameters of acquisition systems based only on acquired radiographic images. These self-calibration methods using range conditions on functions typically require non-truncated data. In this work, we derive range conditions on distributions and demonstrate their application in addressing data truncation issues during the calibration process. We propose a novel approach based on range conditions on distributions, employing Dirac distributions to model markers within the field-of-view of an X-ray system. Our calibration methods are based on the local geometric information from non-truncated projections of a marker set. By applying range conditions to projections of sums of Dirac distributions, combined with specific calibration marker sets, we derive analytical formulas that enable the identification of geometric calibration parameters. We aim to present DCCs on distributions in tomography and explore the potential of DCCs on distributions as a possible tool in calibration. This approach represents one possible application, demonstrating how DCCs on distributions can effectively address challenges such as data truncation and incomplete marker set information. We present results for the 2D parallel geometry (Radon transform) and the 2D fan-beam geometry with sources on a line.
format Preprint
id arxiv_https___arxiv_org_abs_2505_08805
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Range conditions on distributions and their possible application to geometric calibration in 2D parallel and fan-beam geometries
Konik, Anastasia
Desbat, Laurent
Image and Video Processing
Applications
In tomography, range conditions or data consistency conditions (DCCs) on functions have proven useful for geometric self-calibration, which involves identifying geometric parameters of acquisition systems based only on acquired radiographic images. These self-calibration methods using range conditions on functions typically require non-truncated data. In this work, we derive range conditions on distributions and demonstrate their application in addressing data truncation issues during the calibration process. We propose a novel approach based on range conditions on distributions, employing Dirac distributions to model markers within the field-of-view of an X-ray system. Our calibration methods are based on the local geometric information from non-truncated projections of a marker set. By applying range conditions to projections of sums of Dirac distributions, combined with specific calibration marker sets, we derive analytical formulas that enable the identification of geometric calibration parameters. We aim to present DCCs on distributions in tomography and explore the potential of DCCs on distributions as a possible tool in calibration. This approach represents one possible application, demonstrating how DCCs on distributions can effectively address challenges such as data truncation and incomplete marker set information. We present results for the 2D parallel geometry (Radon transform) and the 2D fan-beam geometry with sources on a line.
title Range conditions on distributions and their possible application to geometric calibration in 2D parallel and fan-beam geometries
topic Image and Video Processing
Applications
url https://arxiv.org/abs/2505.08805