Magnetic resonance device having a motion detection unit and a method for detecting a movement of a patient during a magnetic resonance examination

The invention claimed is: 1. A magnetic resonance device comprising: a radiofrequency unit comprising: a radiofrequency antenna; at least one radiofrequency line; and at least one radiofrequency injection point, wherein radiofrequency signals generated by a radiofrequency antenna control unit are transferred to the radiofrequency antenna by the at least one radiofrequency line and injected into the radiofrequency antenna at the at least one radiofrequency injection point; a patient receiving zone that is at least partially enclosed by the radiofrequency antenna; and a motion detection unit comprising a radar unit and operable to detect a movement of a patient that is positionable within the patient receiving zone by at least one radar signal, the radar unit being configured to generate the at least one radar signal, wherein the at least one radar signal has a frequency of at least 3 GHz, wherein the at least one radiofrequency line comprises at least one injection element by which the at least one radar signal generated by the radar unit is coupled into the at least one radiofrequency line, and wherein the radiofrequency antenna is configured to: radiate the radiofrequency signals generated by the radiofrequency antenna control unit into the patient receiving zone via the at least one radiofrequency line and the at least one radiofrequency injection point; emit the at least one radar signal generated by the radar unit into the patient receiving zone, such that the movement of the patient is detectable, the at least one radar signal being transmittable from the radar unit to the radiofrequency antenna via the at least one radiofrequency line and the at least one radiofrequency injection point; and acquire at least one reflected radar signal, the at least one reflected radar signal being transmittable from the radiofrequency antenna to the radar unit via the radiofrequency line and the at least one injection element. 2. The magnetic resonance device of claim 1 , wherein the at least one reflected radar signal is acquired by the radiofrequency antenna, and wherein the at least one reflected radar signal is configured to be reflected off the patient that is introducible into the patient receiving zone. 3. The magnetic resonance device of claim 1 , wherein the at least one radar signal has a maximum frequency of 30 GHz. 4. The magnetic resonance device of claim 1 , wherein the at least one radiofrequency line comprises two or more radiofrequency lines, and the at least one radiofrequency injection point comprises two or more radiofrequency injection points, and wherein a radiofrequency signal of the radiofrequency signals generated by the radiofrequency antenna control unit is transferred in each case to one radiofrequency injection point of the two or more radiofrequency injection points by the two or more radiofrequency lines, and each of the two or more radiofrequency lines has an injection element for injecting a radar signal of the at least one radar signal into the radiofrequency antenna, the two or more radiofrequency lines injecting two or more radar signals into the radiofrequency antenna, respectively. 5. The magnetic resonance device of claim 4 , wherein the motion detection unit comprises a switching unit, and the two or more radar signals are injected into the radiofrequency antenna by the switching unit. 6. The magnetic resonance device of claim 4 , wherein the motion detection unit comprises an evaluation unit configured to combine the two or more radar signals with one another. 7. The magnetic resonance device of claim 1 , wherein two or more radar signals of the at least one radar signal are injected into the radiofrequency antenna by a single radiofrequency injection point and a single radiofrequency line having a single injection element, and wherein the two or more radar signals are embodied differently in terms of a radar frequency. 8. The magnetic resonance device of claim 1 , wherein the at least one injection element comprises a directional coupler. 9. The magnetic resonance device of claim 8 , wherein the motion detection unit comprises an adapter unit. 10. The magnetic resonance device of claim 1 , wherein the movement of the patient comprises a cardiac motion, a respiratory motion, or the cardiac motion and the respiratory motion of the patient. 11. The magnetic resonance device of claim 1 , wherein the radiation of the radiofrequency signals, the emission of the at least one radar signal, the acquisition of the at least one reflected radar signal, or any combination thereof is performed simultaneously by the radiofrequency antenna. 12. A method for detecting a movement of a patient during a magnetic resonance examination by a magnetic resonance device, wherein the magnetic resonance device comprises a radiofrequency antenna and a motion detection unit, the motion detection unit comprising a radar unit, the method comprising: generating, by the radar unit, at least one radar signal, wherein the at least one radar signal has a frequency of at least 3 GHz; transmitting, by the radiofrequency antenna, the at least one generated radar signal; acquiring, by the radiofrequency antenna, at least one reflected radar signal; evaluating the at least one reflected radar signal for the purpose of detecting a movement of the patient; and radiating radiofrequency signals generated by a radiofrequency antenna control unit into a patient receiving zone using the radiofrequency antenna. 13. The method of claim 12 , wherein the at least one generated radar signal is coupled into at least one radiofrequency line by at least one injection element, and wherein the radiofrequency signals are transferred to the radiofrequency antenna by the at least one radiofrequency line. 14. The method of claim 13 , wherein the at least one reflected radar signal acquired by the radiofrequency antenna is coupled out of a radiofrequency line of the at least one radiofrequency line by the at least one injection element, and wherein the radiofrequency signals are transferred to the radiofrequency antenna by the at least one radiofrequency line. 15. The method of claim 12 , wherein acquiring the at least one reflected radar signal further comprises (1) acquiring different radar signals that differ from one another in terms of a radar frequency, (1) acquiring different radar signals that differ from one another in terms of a radiofrequency injection point into the radiofrequency antenna, or (1) acquiring different radar signals that differ from one another in terms of a radar frequency and (2) acquiring different radar signals that differ from one another in terms of a radiofrequency injection point into the radiofrequency antenna, and wherein the method further comprises combining the different radar signals with one another to determine the movement of the patient.