Abstract
Spectral and grating-based differential phase-contrast (DPC) x-ray imaging are two emerging technologies that offer additional information compared with conventional attenuation-based x-ray imaging. In the case of spectral imaging, energy-resolved measurements allow the generation of material-specific images by exploiting differences in the energy-dependent attenuation. DPC imaging uses the phase shift that an x-ray wave exhibits when traversing an object as contrast generation mechanism. Recently, we have investigated the combination of these two imaging techniques (spectral DPC imaging) and demonstrated potential advantages compared with spectral imaging. In this work, we present a noise analysis framework that allows the prediction of (co-) variances and noise power spectra for all three imaging methods. Moreover, the optimum acquisition parameters for a particular imaging task can be determined. We use this framework for a performance comparison of all three imaging methods. The comparison is focused on (projected) electron density images since they can be calculated with all three imaging methods. Our study shows that spectral DPC imaging enables the calculation of electron density images with strongly reduced noise levels compared with the other two imaging methods for a large range of clinically relevant pixel sizes. In contrast to conventional DPC imaging, there are no long-range noise correlations for spectral DPC imaging. This means that excessive low frequency noise can be avoided. We confirm the analytical predictions by numerical simulations.
Highlights
Spectral and grating-based differential phase-contrast (DPC) x-ray imaging are two emerging technologies that offer additional information compared to conventional attenuation-based x-ray imaging.In the case of spectral imaging, information about the energy-dependent attenuation of an object is obtained by acquiring measurements with two or more photon energy spectra
A possible explanation for these results can be found by looking at figure 3, which shows the energydependent visibility as well as the effective spectra for DPC and spectral differential phase-contrast (SDPC) imaging with optimum setup parameters
We have developed a noise analysis framework that allows the calculation of variances and noise power spectra for spectral, DPC and SDPC imaging
Summary
Spectral and grating-based differential phase-contrast (DPC) x-ray imaging are two emerging technologies that offer additional information compared to conventional attenuation-based x-ray imaging.In the case of spectral imaging, information about the energy-dependent attenuation of an object is obtained by acquiring measurements with two or more photon energy spectra. Spectral and grating-based differential phase-contrast (DPC) x-ray imaging are two emerging technologies that offer additional information compared to conventional attenuation-based x-ray imaging. Grating-based DPC imaging exploits an entirely different contrast generating mechanisms in addition to the conventional attenuation contrast: the phase-contrast image is obtained by indirectly measuring the (differ ential) phase shift that an x-ray wave exhibits when transversing an object (Pfeiffer et al 2006, 2007). This differential phase shift can be directly related to the projected electron density (PED) of the object. Experimental studies have demonstrated that to spectral imaging, material-specific information can be extracted from phase-contrast measurements (Braig et al 2018)
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