where X(s) and Y(s) represent the c

where X(s) and Y(s) represent the coordinates of all voxels inside the sample that contribute to the absorption of the primary beam along ray S and s is the coordinate along the beam axis. In the (X, Y, Z) coordinate system of the sample, the Z-axis coincides with the axis of rotation, while in the XY plane the X-axis makes an angle ωk relative to the beam axis.
During the reconstruction phase of the tomographic analysis, the original dataset ITRANS(x, z, ω)/I0 is transformed into a three dimensional distribution of the linear X-ray absorption coefficient μL(x, y, z) throughout the object. Since the object needs to be moved only along one axis (ω-rotation) while the transmitted intensity at all (x, z) combinations is recorded simultaneously, third generation tomography can achieve a high degree of parallelism, allowing measurements to be performed in an efficient and rapid fashion. Accordingly, provided the object is transparent enough for the X-rays being used, both the speed and spatial resolution of X-ray absorption tomography are largely determined by the camera characteristics. TheμL(x, y, z) distribution essentially reflects the variation in density and composition within the examined object but does not containmore detailed information, e.g. on the nature of the various chemical elements or material phases that may be present. In transmission tomography, in addition to employing absorption contrast, also other contrast mechanisms such as phase contrast may be employed: for example, holotomography[3] allows the discrimination between materials with similar absorption characteristics but a different refractive index in the X-ray regime.