Digital amplitude control and digital phase control of a high-frequency signal

The invention claimed is: 1. A method for digital amplitude control and digital phase control of a high-frequency signal, the method comprising: providing a digital command signal that specifies in complex form, comprising a real subcomponent and an imaginary subcomponent, an amplitude and a phase of the high-frequency signal that is to be controlled; outputting a digital activation signal comprising a real subcomponent and an imaginary subcomponent to a high-frequency unit for generating the high-frequency signal; receiving a digital signal deviation value in complex form comprising a real subcomponent and an imaginary subcomponent, wherein the digital signal deviation value expresses a deviation of the high-frequency signal from the digital command signal with respect to the amplitude and the phase; and determining the digital activation signal from the digital command signal while taking into consideration the digital signal deviation value, wherein the determination of the real subcomponent and the imaginary subcomponent of the digital activation signal occurs separately in each case. 2. The method as claimed in claim 1 , further comprising: correcting a characteristic curve before the output of the digital activation signal; calculating an amplitude of the digital activation signal from the real subcomponent and the imaginary subcomponent of the digital activation signal; and complex multiplying, as a function of the amplitude of the digital activation signal, the digital activation signal by a specific correction factor from a plurality of complex correction factors. 3. The method as claimed in claim 2 , wherein the plurality of complex correction factors are stored in a table and take into consideration a nonlinear characteristic curve of a subsequent high-frequency amplifier. 4. The method as claimed in claim 1 , further comprising normalizing the amplitude of the digital command signal to a value of “1” such that the value “1” corresponds to a highest expected command amplitude. 5. The method as claimed in claim 4 , wherein an activation signal having an amplitude that is normalized to the value “1” corresponds to a normalized command signal having the value “1”. 6. The method as claimed in claim 5 , wherein an output signal of a subsequent high-frequency amplifier at maximal amplitude corresponds to the normalized activation signal having the value “1”. 7. The method as claimed in claim 1 , wherein the high-frequency signal is a pulse sequence, and an amplitude of the digital activation signal is normalized to a value “1”, which corresponds to an output signal of a subsequent high-frequency amplifier at maximal amplitude, wherein the digital activation signal is determined from the digital command signal while taking into consideration the digital signal deviation value and while taking into consideration a highest expected command amplitude within a pulse. 8. The method as claimed in claim 1 , wherein the high-frequency signal is a pulse sequence, and the real subcomponent of the digital signal deviation value is changed as a function of a highest expected real subcomponent of the digital command signal for the current pulse in each case, such that an addition of the real subcomponent of the digital command signal and the real subcomponent of the digital signal deviation value does not exceed the value “1”, and wherein the imaginary subcomponent of the digital signal deviation value is changed as a function of a highest expected imaginary subcomponent of the digital command signal for the current pulse in each case, such that an addition of the imaginary subcomponent of the digital command signal and the imaginary subcomponent of the digital signal deviation value does not exceed the value “1”. 9. The method as claimed in claim 8 , wherein the change of the real subcomponent and the imaginary subcomponent of the digital signal deviation value also takes place such that an amplitude of the digital activation signal does not exceed the value “1”. 10. The method as claimed in claim 8 , further comprising multiplying the real subcomponent, the imaginary subcomponent, or the real subcomponent and the imaginary subcomponent of the digital signal deviation value by a factor in each case, such that a continuous change of the digital command signal is effected as a function of the highest expected real subcomponent or the highest expected imaginary subcomponent. 11. The method as claimed in claim 10 , further comprising: routing the real subcomponent and the imaginary subcomponent of the digital signal deviation value via a controller before the multiplication in each case; and scaling an output value of the controllers such that a value of “1” is not exceeded. 12. The method as claimed in claim 8 , wherein the change of the real subcomponent, the imaginary subcomponent, or the real subcomponent and the imaginary subcomponent of the digital signal deviation value only occurs if the value “1” for the sum of the imaginary subcomponent of the digital command signal and the imaginary subcomponent of the digital signal deviation value, or for the sum of the real subcomponent of the digital command signal and the real subcomponent of the digital signal deviation value would otherwise be exceeded, if the value “1” for the amplitude of the digital activation signal would otherwise be exceeded, or a combination thereof. 13. The method as claimed in claim 12 , further comprising routing the real subcomponent and the imaginary subcomponent of the digital signal deviation value via a controller before the possible change in each case. 14. The method as claimed in claim 2 , further comprising normalizing the amplitude of the digital command signal to a value of “1” such that the value “1” corresponds to a highest expected command amplitude. 15. The method as claimed in claim 14 , wherein an activation signal having an amplitude that is normalized to the value “1” corresponds to a normalized command signal having the value “1”. 16. The method as claimed in claim 15 , wherein an output signal of a subsequent high-frequency amplifier at maximal amplitude corresponds to the normalized activation signal having the value “1”. 17. The method as claimed in claim 2 , wherein the high-frequency signal is a pulse sequence, and an amplitude of the digital activation signal is normalized to a value “1”, which corresponds to an output signal of a subsequent high-frequency amplifier at maximal amplitude, wherein the digital activation signal is determined from the digital command signal while taking into consideration the digital signal deviation value and while taking into consideration a highest expected command amplitude within a pulse. 18. The method as claimed in claim 2 , wherein the high-frequency signal is a pulse sequence, and the real subcomponent of the digital signal deviation value is changed as a function of a highest expected real subcomponent of the digital command signal for the current pulse in each case, such that an addition of the real subcomponent of the digital command signal and the real subcomponent of the digital signal deviation value does not exceed the value “1”, and wherein the imaginary subcomponent of the digital signal deviation value is changed as a function of a highest expected imaginary subcomponent of the digital command signal for the current pulse in each case, such that an addition of the imaginary subcomponent of the digital command signal and the imaginary subcomponent of the digital signal deviation value does not exceed the value “1”.