Calibration of imagers with dynamic beam shapers

The invention claimed is: 1. A calibration method for an imager having an adjustable filter arranged between a radiation source of the imager and a detector of the imager, the filter suitable to effect, by adjustment of the filter's setting, different non-homogenous energy intensity profiles of a radiation beam generated by the radiation source before passage of said beam through an object to be imaged, the method comprising: adjusting the filter for a plurality of different basis filter settings, one at a time; acquiring at the imager's detector a plurality of basis gain images, at least one gain image for each of the different filter settings; and synthesizing a target gain image from the one or more of the plurality of gain images, wherein the synthesizing step includes forming a linear combination from one or more of the plurality of basis gain images, wherein the linear combination involves weights each weight representing an individual attenuation strength of a respective ones of filter elements of the filter. 2. Method of claim 1 , wherein each of the basis gain images record a different attenuation profile that is caused by a respective, locally restricted attenuation of the adjustable filter. 3. The method of claim 2 , wherein the attenuation profile as recorded in each gain image is a different single-dip profile. 4. The method of claim 2 , wherein the filter elements are individually addressable to effect an essentially pointwise or at least localized pre-attenuation of the beam, wherein the single dip attenuation profiles each correspond to an attenuation of a respective one of the filter elements. 5. The method of claim 1 , wherein the step of synthesizing the target gain image is executed in response to receiving a shape specification of an object to be imaged. 6. A calibration method for an imager having an adjustable filter arranged between a radiation source of the imager and a detector of the imager, the filter suitable to effect, by adjustment of the filter's setting, different non-homogenous energy intensity profiles of a radiation beam generated by the radiation source before passage of said beam through an object to be imaged, the method comprising: receiving at least one specification of a shape of the object; adjusting the filter for a plurality of different filter settings, one at a time; acquiring at the imager's detector a plurality of gain images, at least one gain image for each of the different filter settings, wherein the imager's x-ray source is rotatable about an examination region, wherein each of the gain images are acquired at different views with the filter setting adjusted at step in dependence on the different views and/or the received object shape specification. 7. The method of claim 6 , further comprising the step of: optically scanning the object to obtain the object shape specification received at step. 8. The method of claim 6 , wherein the different filter settings are pre-stored in a database and wherein the adjustment step includes selecting for each view a filter setting from said pre-stored filter settings, each pre-stored filter stetting associated with the respective view on the object shape, the selection being dependent on the received object shape specification and/or view and/or wherein the plurality of detector gain images are stored in a gain image repository. 9. The method of claim 6 , wherein the scanning step and the gain image acquiring step is synchronized with the respective view. 10. An imager calibrated according to the method of claim 1 . 11. The imager of claim 10 , wherein the imager is a 3D CT imager or a 2D X-ray imager, in particular, an interventional 2D X-ray imager of the C-arm type. 12. An imaging system including an imager and a calibration controller configured to carry out the method steps according to claim 1 . 13. An imaging system including an imager and a calibration controller configured to carry out the method steps according to claim 5 , further including an optical scanner for supplying the shape specification of the object.