Abstract
Beam hardening and scattering effects can seriously degrade image quality in polychromatic X-ray CT imaging. In recent years, polychromatic image reconstruction techniques and scatter estimation using Monte Carlo simulation have been developed to compensate for beam hardening and scattering CT artifacts, respectively. Both techniques require knowledge of the X-ray tube energy spectrum. In this work, Monte Carlo simulations were used to calculate the X-ray energy spectrum of FleXCT, a novel prototype industrial micro-CT scanner, enabling beam hardening and scatter reduction for CT experiments. Both source and detector were completely modeled by Monte Carlo simulation. In order to validate the energy spectra obtained via Monte Carlo simulation, they were compared with energy spectra obtained via a second method. Here, energy spectra were calculated from empirical measurements using a step wedge sample, in combination with the Maximum Likelihood Expectation Maximization (MLEM) method. Good correlation was achieved between both approaches, confirming the correct modeling of the FleXCT system by Monte Carlo simulation. After validation of the modeled FleXCT system through comparing the X-ray spectra for different tube voltages inside the detector, we calculated the X-ray spectrum of the FleXCT X-ray tube, independent of the flat panel detector response, which is a prerequisite for beam hardening and scattering CT artifacts.
Highlights
Interest in modeling and/or characterizing an X-ray energy spectrum of a modernX-ray instrument highly depends on its specific application
Scannerscanner was simulated and the emitted X-ray energy spectrum was calculated in front of the target just after the and the emitted
X-ray energy spectra obtained both from Monte Carlo simulation and Maximum Likelihood Expectation Maximization (MLEM)
Summary
Interest in modeling and/or characterizing an X-ray energy spectrum of a modernX-ray instrument highly depends on its specific application. Interest in modeling and/or characterizing an X-ray energy spectrum of a modern. For X-ray micro-CT applications, information on the X-ray energy spectrum can be used to compensate for artifacts that arise due to interaction of photons with the object being scanned, such as beam hardening [1] or scatter artifacts [2,3]. Aside from that, knowledge on the X-ray tube spectrum can be used to mitigate artifacts that arise due to flat-field correction [4] or to discriminate between different materials present within the object [5]. Since the invention of the first modern X-ray tube in 1916 [11], the estimation of the spectral composition of the emitted X-ray radiation has been investigated and addressed in many ways. Energy-resolving detectors, such as cadmium telluride [12]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
