Email this article GEOMETRICAL ABERRATION CORRECTION METHOD FOR COMPUTER RADIOGRAPHY SYSTEM SCANNING DEVICES
- Authors: Ekimov Y.M.1, Cossack A.O.1, Kovalev E.O.1, Malyshev M.A.1, Nikitin O.A.1, Sergeev A.V.1, Stavrietsky V.I.1, Yaskevich A.P.1
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Affiliations:
- Federal State Unitary Enterprise «Russian Federal Nuclear Center — Zababakhin All-Russia Research Institute of Technical Physics»
- Issue: No 10 (2025)
- Pages: 68-75
- Section: Рентгеновские методы
- URL: https://journals.rcsi.science/0130-3082/article/view/302889
- DOI: https://doi.org/10.31857/S0130308225100071
- ID: 302889
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Abstract
The paper describes a practically implemented method for correcting the geometrical aberrations introduced by a scanning device as a proposed stage of the computer radiography system qualification. The presence of geometrical distortions in the scanned images affects the metrological characteristics of the measurement methods and techniques that are using these systems. The method allows for correction of a systematic error obtained when scanning photostimulable phosphor detectors on the digital radiography devices. The main stages of method implementation include fabrication of the calibration sample, conducting reference instrumental measurements, comparing reference measurements with digital image processing results, and estimation and correcting the errors. During the period 2022 to 2024, the examination results for three scanning devices were analyzed. The use of the geometrical aberration correction method allows for minimization of distortions as well as estimation of quality and stability of the scanning devices
About the authors
Yuri Mikhailovich Ekimov
Federal State Unitary Enterprise «Russian Federal Nuclear Center — Zababakhin All-Russia Research Institute of Technical Physics»
Email: vniitf@vniitf.ru
Russian Federation, 456770 Chelyabinsk region, Snezhinsk, Vasilieva str., 13
Alexey Olegovich Cossack
Federal State Unitary Enterprise «Russian Federal Nuclear Center — Zababakhin All-Russia Research Institute of Technical Physics»
Email: vniitf@vniitf.ru
Russian Federation, 456770 Chelyabinsk region, Snezhinsk, Vasilieva str., 13
Evgeny Olegovich Kovalev
Federal State Unitary Enterprise «Russian Federal Nuclear Center — Zababakhin All-Russia Research Institute of Technical Physics»
Email: vniitf@vniitf.ru
Russian Federation, 456770 Chelyabinsk region, Snezhinsk, Vasilieva str., 13
Michael Alexandrovich Malyshev
Federal State Unitary Enterprise «Russian Federal Nuclear Center — Zababakhin All-Russia Research Institute of Technical Physics»
Email: vniitf@vniitf.ru
Russian Federation, 456770 Chelyabinsk region, Snezhinsk, Vasilieva str., 13
Oleg Alfredovich Nikitin
Federal State Unitary Enterprise «Russian Federal Nuclear Center — Zababakhin All-Russia Research Institute of Technical Physics»
Email: vniitf@vniitf.ru
Russian Federation, 456770 Chelyabinsk region, Snezhinsk, Vasilieva str., 13
Alexander Viktorovich Sergeev
Federal State Unitary Enterprise «Russian Federal Nuclear Center — Zababakhin All-Russia Research Institute of Technical Physics»
Author for correspondence.
Email: nemat1k@mail.ru
Russian Federation, 456770 Chelyabinsk region, Snezhinsk, Vasilieva str., 13
Valentin Ivanovich Stavrietsky
Federal State Unitary Enterprise «Russian Federal Nuclear Center — Zababakhin All-Russia Research Institute of Technical Physics»
Email: vniitf@vniitf.ru
Russian Federation, 456770 Chelyabinsk region, Snezhinsk, Vasilieva str., 13
Alena Pavlovna Yaskevich
Federal State Unitary Enterprise «Russian Federal Nuclear Center — Zababakhin All-Russia Research Institute of Technical Physics»
Email: vniitf@vniitf.ru
Russian Federation, 456770 Chelyabinsk region, Snezhinsk, Vasilieva str., 13
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