C-arm system with extended field of view

The invention claimed is: 1. A C-arm X-ray imaging system, provided to acquire extended three-dimensional images of an object, the imaging system comprising: a C-arm structure with an X-ray source and an X-ray detector mounted across from the X-ray source; a motorized drive for a rotational movement of the C-arm structure; and a control unit; wherein the C-arm structure is provided to perform a rotational scan around an axis of rotation and around an ISO-center acquiring a number of X-ray projections for generating image data of a reconstructed three-dimensional field of view; the control unit is configured to control the motorized drive; and the control unit is configured to cause the rotational movement of the C-arm structure to perform: a first rotational X-ray scan around a first ISO-center with a first axis of rotation for a first field of view; and a second rotational X-ray scan around a second ISO-center with a second axis of rotation for a second field of view; the first and the second ISO-center are displaced in relation to each other such that a connection line between the first and the second ISO-centers is arranged transverse to the first and the second axes of rotation; and the control unit is configured to provide a convex as an extended three-dimensional field of view enclosing the first field of view and the second field of view and residual region, which residual regions are located inside the convex hull, but outside the first and second fields of view. 2. The C-arm X-ray imaging system according to claim 1 , wherein: the C-arm structure is configured to perform the first rotational X-ray scan with a first trajectory and the second rotational X-ray scan with a second trajectory displaced to the first trajectory; and the first and the second trajectory have the same trajectory shape. 3. The C-arm X-ray imaging system according to claim 1 , wherein the control unit is configured to cause the rotational movement of the C-arm structure to perform the rotational scans such that the first and the second field of view contact each other. 4. The C-arm X-ray imaging system according to claim 1 , wherein the first and second axes of rotation are displaced parallel to each other such that the connection line between the first and the second ISO-centers is arranged perpendicular to the first and the second axes of rotation. 5. The C-arm X-ray imaging system according to claim 1 , wherein the C-arm structure is provided to perform the first and the second rotational scans as a circular arc respectively. 6. The C-arm X-ray imaging system according to claim 1 , wherein: the control unit is configured to use projection data from the first rotational X-ray scan for a reconstruction of the first field of view and projection data from the second rotational X-ray scan for a reconstruction of the second field of view; and the control unit is configured to use projection data from the first field of view and projection data from the second field of view for a reconstruction of the residual regions. 7. The C-arm X-ray imaging system according to claim 1 , wherein: the control unit is configured to use projection data from voxel-covering segments for reconstructing a voxel inside the residual regions, and the voxel-covering segments are segments of the first and/or second rotational X-ray scans, which segments comprise acquisition points for which the voxel that is to be reconstructed is located inside the respective first and/or second field of view of a particular acquisition point. 8. A method for acquiring three-dimensional (3D) X-ray image data of an object, the method comprising: a) performing a first rotational X-ray scan comprising a first field of view around a first ISO-center; b) performing a second rotational X-ray scan comprising a second field of view around a second ISO-center; wherein: the first and the second ISO-centers of rotation are displaced in relation to each other such that a connection line between the first and the second ISO-center is arranged transverse to the first and the second axes of rotation; and c) providing a convex hull is provided as an extended three-dimensional field of view enclosing the first field of view and the second field of view and residual regions, which residual regions are located inside the convex hull, but outside the first and second fields of view. 9. The method according to claim 8 , wherein: the first rotational X-ray scan in step a) is performed with a first trajectory; the second rotational X-ray scan in step b) is performed with a second trajectory displaced to the first trajectory; and the first and the second trajectory have the same trajectory shape. 10. The according to claim 8 , wherein at least one of the following group is provided: i) the first and the second ISO-center are displaced such that the first and second fields of view contact each other; ii) the first and second axes of rotation are displaced parallel to each other such that the connection line between the first and the second ISO-centers is arranged perpendicular to the first and the second axes of rotation; and iii) the first and the second rotational scans are performed as a circular arc respectively. 11. The method according to claim 8 , wherein: for a reconstruction of the first field of view, projection data from the first rotational X-ray scan is used; a reconstruction of the second field of view, projection data from the second rotational X-ray scan is used; and for a reconstruction of the residual regions, projection data from the first field of view and projection data from the second field of view used. 12. The method according to claim 8 , wherein: for reconstructing a voxel inside the residual regions, projection data from voxel-covering segments is used; and the voxel-covering segments are segments of the first and/or second rotational X-ray scans, which segments comprise acquisition points for which the voxel that is to be reconstructed is located inside the respective first and/or second field of view of a particular acquisition point. 13. The method according to claim 12 , wherein for reconstructing the voxel inside the residual regions, differentiated back-projected projection data along the voxel-covering segments is used. 14. A non-transitory computer readable storage medium storing instructions that when executed by a processor perform the method defined by claim 8 . 15. The imaging system of claim 1 , wherein: the first field of view is a region of the object through which every X-ray projection of the first rotational X-ray scan passes, the second field of view is another region of the object through which every X-ray projection of the second rotational X-ray scan passes, and the control unit uses X-ray projection data solely from the first rotational X-ray scan for a reconstruction of the first field of view within the extended three-dimensional field of view and uses X-ray projection data solely from the second rotational X-ray scan for a reconstruction of the second field of view within the extended three-dimensional field of view. 16. The imaging system of claim 15 , wherein: the residual regions are regions of the object through which: some, but not all, X-ray projections of the first rotational X-ray scan pass, and some, but not all, X-ray projections of the second rotational X-ray scan pass, and the control unit uses X-ray projection data from each of the first and second rotational X-ray scans to produce a reconstruction of the residual regions. 17. The imaging syst