X-ray system and method to generate image data

I claim as my invention: 1. An x-ray system, comprising: an x-ray source that emits x-ray radiation; a radiation detector located in a path of said x-ray radiation that detects at least x-ray radiation attenuated by an examination subject irradiated by said x-ray radiation, and that generates two-dimensional radiation detector data corresponding to said x-ray radiation attenuated by the examination subject; a monitor detector irradiated by said x-ray radiation emitted by said x-ray source that does not travel through said examination subject, said monitor detector being configured as an energy-resolving detector to generate energy-resolved current dose measurement data representing a current dose of said x-ray radiation; and said monitor detector comprising at least two detector elements located in succession in a direction of propagation of said x-ray radiation, each of said at least two detector elements being a detector element selected from the group consisting of an energy-integrating detector element and a photon-counting detector element. 2. An x-ray system as claimed in claim 1 , wherein said x-ray source and said radiation detector are configured to operate as a computed tomography system, with said two-dimensional radiation detector data generated by said radiation detector representing projection data obtained by irradiation of an examination subject from respectively different directions. 3. An x-ray system as claimed in claim 1 , comprising a control unit configured to control said radiation detector and said monitor detector to synchronously acquire said two-dimensional radiation detector data from said radiation detector and said energy-resolved current dose measurement data from said monitor detector. 4. An x-ray system as claimed in claim 3 , wherein said control unit is configured to operate said radiation detector and said monitor detector to acquire said two-dimensional radiation detector data from said radiation detector and said energy-resolved current dose measurement data from said monitor detector temporally in parallel. 5. An x-ray system as claimed in claim 3 , wherein said control unit is configured to operate said radiation detector and said monitor detector to acquire said two-dimensional radiation detector data from said radiation detector and said energy-resolved current dose measurement data from said monitor detector linked together with a temporal correlation. 6. An x-ray system as claimed in claim 5 , comprising an image generation unit supplied with said two-dimensional radiation detector data from said radiation detector and said energy-resolved current dose measurement data from said monitor detector, and configured to generate image data from said two-dimensional radiation detector data acquired by said radiation detector also using said temporally correlated energy-resolved current dose measurement data from said monitor detector. 7. An x-ray system as claimed in claim 1 , wherein said x-ray source comprises a diaphragm that limits a size of a cross-section of said x-ray radiation, and wherein said monitor detector is arranged at said diaphragm facing toward said x-ray source. 8. An x-ray system as claimed in claim 1 , wherein said monitor detector is located at said radiation detector. 9. An x-ray system as claimed in claim 1 , wherein said monitor detector is integrated into said radiation detector. 10. An x-ray system as claimed in claim 1 , wherein said monitor detector comprises at least two energy-integrating detector elements and respectively different radiation filters respectively located upstream, with respect to a direction of propagation of said x-ray radiation, of said at least two energy-integrating detector elements. 11. An x-ray system as claimed in claim 1 , wherein said monitor detector comprises at least one photon-counting detector element comprising at least two different energy thresholds. 12. A method to operate an x-ray imaging system, comprising: irradiating an examination subject with x-ray radiation emitted from an x-ray source; detecting, with a radiation detector, said x-ray radiation attenuated by the examination subject and generating, from said radiation detector, two-dimensional radiation detector data representing the x-ray radiation attenuated by the examination subject; providing an energy-resolving monitor detector comprising at least two detector elements located in succession in a direction of propagation of said x-ray radiation, each of said at least two detector elements being a detector element selected from the group consisting of an energy-integrating detector element and a photon-counting detector element; with said energy-resolving monitor detector, detecting current dose measurement data of a portion of said x-ray radiation that does not proceed through the examination subject; and respectively emitting said two-dimensional radiation detector data and said energy-resolved current dose measurement data from said radiation detector and said monitor detector as respective electronic signals. 13. A method as claimed in claim 12 , comprising, from a control unit, operating said x-ray source and said radiation detector as a computed tomography system to acquire said two-dimensional radiation detector data from said radiation detector as respective sets of projection data obtained by irradiating the examination subject from different directions. 14. A method as claimed in claim 12 , comprising operating said x-ray source with respectively different x-ray energies in different time segments, and detecting energy data of said x-ray radiation in said different time segments from said energy-resolved dose measurement data acquired with said monitor detector. 15. A method to generate image data of an examination subject, comprising: providing a processor with two-dimensional radiation detector data from a radiation detector, said two-dimensional radiation detector data representing x-ray radiation attenuated by an examination subject; providing an energy-resolving monitor detector comprising at least two detector elements located in succession in a direction of propagation of said x-ray radiation, each of said at least two detector elements being a detector element selected from the group consisting of an energy-integrating detector element and a photon-counting detector element; providing said processor with energy-resolved current dose measurement data acquired by said energy-resolving monitor detector from a portion of said x-ray radiation that does not proceed through the examination subject; and in said processor, executing an image reconstruction algorithm to generate image data of the examination subject from said two-dimensional radiation detector data and said energy-resolved current dose measurement data. 16. A method as claimed in claim 15 , comprising providing said processor with sets of projection data, as said two-dimensional radiation detector data, respectively acquired by irradiating the examination subject from different directions. 17. A method as claimed in claim 15 , comprising using said energy-resolved current dose measurement data in said image reconstruction algorithm to modify said two-dimensional detector data. 18. A method as claimed in claim 15 , comprising, in said image reconstruction algorithm, using said energy-resolved dose measurement data to generate energy data representing an energy of the x-ray radiation, and using said energy data to generate mixed image data from said two-dimensional radiation detector data, said two-dimensional radiation det