Operation of a transmission device of a magnetic resonance device

The invention claimed is: 1. A method for operating a transmission device of a magnetic resonance device, the transmission device being configured to independently actuate a plurality of coil elements of a radiofrequency coil over different transmission paths, wherein phase differences in a reference plane are taken into consideration to actuate the plurality of coil elements with different phases, the method comprising: measuring, by an internal measuring device installed permanently in the transmission device spaced apart from the reference plane, a first phase of a transmitted radiofrequency signal in a first calibration measurement performed once for each transmission path; measuring, by an external measuring device to be connected to the reference plane, a second phase of the transmitted radiofrequency signal for the first calibration measurement; and determining, for each transmission path, a correction value from a difference between the first phase and the second phase and subtracting the determined correction value from following measurements with the internal measuring device in order to determine a present phase at the reference plane, subtracting, for each transmission path, the second phase from a target phase for determining an actuation phase, with which a radiofrequency signal is generated in order to obtain the target phase at the reference plane, or a combination thereof, wherein at least one phase of the first phase and the second phase is taken into consideration in the phase-accurate actuating of the plurality of coil elements, for correcting further measurements with the internal measuring device, or a combination thereof. 2. The method of claim 1 , wherein the reference plane is at plug-in location for the plurality of coil elements. 3. The method of claim 1 , further comprising using, in each case, one directional coupler that is connected to a receiver having an analog-to-digital converter as the internal measuring device and the external measuring device. 4. The method of claim 3 , wherein the receiver that is associated with the external measuring device and is installed permanently in the transmission device is used exclusively for the external measuring device. 5. The method of claim 3 , wherein the receivers for the internal measuring devices are also used for receiving magnetic resonance signals with the radiofrequency coil. 6. The method of claim 3 , further comprising: generating signals on the transmission paths using one modulator in each case, wherein the internal measuring devices each include one of the modulators or the receiver; during the first calibration measurement, comparing the phases of all of the receivers with a phase of a predetermined reference modulator of the modulators and storing discrepancies as receiver reference phases, comparing the phases of all of the modulators with a phase of a predetermined reference receiver of the receivers and storing discrepancies as modulator reference phases, or a combination thereof; during a second calibration measurement following restarting of the transmission device, comparing the phases of all of the receivers with the phase of the predetermined reference modulator, and storing discrepancies as present receiver phases, comparing the phases of all of the modulators with the phase of the predetermined reference receiver and storing discrepancies as present modulator phases, or a combination thereof, wherein, after every second calibration measurement, in the case of phase-accurate actuating, correction, or phase-accurate actuating and correction, for each transmission path, at least one of the differences between the present receiver phase and the receiver reference phase and between the present modulator phase and the modulator reference phase is taken into consideration. 7. The method of claim 1 , further comprising: transmitting a clearly defined test signal on each transmission path as part of the first calibration measurement; measuring, for each test signal using the internal measuring device, an amplitude and a phase of a forward test signal and a return test signal, and storing the amplitude and the phase of the forward test signal and the return test signal as check values, wherein at at least one later point in time in a check measurement with the same configuration, for each transmission path, the test signal is transmitted again and, for each test signal, the amplitude and the phase of the forward and the return test signal are measured by the internal measuring device; and establishing and outputting a cable fault when there is a discrepancy in the check values for a transmission path. 8. The method of claim 6 , wherein the at least one difference is taken into consideration such that the difference between the present receiver phase and the receiver reference phase is added to the correction value determined as the difference between the first phase and the second phase, after every second calibration measurement, the difference between the present modulator phase and the modulator reference phase is subtracted from the target phase for determining the actuation phase, or a combination thereof. 9. The method of claim 6 , wherein the second calibration measurement is performed automatically every time the transmission device is restarted. 10. The method of claim 6 , further comprising determining the receiver reference phases and the present receiver phases, the determining comprising distributing a comparison signal of the determined reference modulator among the receivers using a splitter. 11. The method of claim 10 , further comprising determining the modulator reference phases and the present modulator phases, the determining comprising passing the comparison signal of the modulators on to the specific reference receiver via a combiner. 12. A transmission device for a magnetic resonance device, the transmission device being configured for independently actuating a plurality of coil elements of a radiofrequency coil, the transmission device comprising: a plurality of transmission paths, each transmission path of the plurality of transmission paths comprising: a modulator; an amplifier device; an internal measuring device connected downstream of the amplifier device, the internal measuring device configured for measuring a first phase of a transmitted radiofrequency signal; a plug-in location considered as reference plane for a coil element of the plurality of coil elements; an external measuring device that is connectable to the plug-in location, the external measuring device configured for measuring a second phase of a transmitted radiofrequency signal; and a control device configured to: operate the transmission device; measure, using the internal measuring device, which is installed permanently in the transmission device spaced apart from the reference plane, the first phase of the transmitted radiofrequency signal in a first calibration measurement performed once for each transmission path of the plurality of transmission paths; and measure, using the external measuring device connected to the reference plane, the second phase of the transmitted radiofrequency signal for the first calibration measurement; and take at least one phase of the first phase and the second phase into consideration in the phase-accurate actuating of the plurality of coil elements, for correcting further measurements with the internal measuring device, or a combination thereof, wherein the transmission device is further configured to independently actuate the plurality of coil elements of the radiofrequency coil over the plurality of transmission paths, and wherein the contr