Control device and plasma energy protective apparatus for an ion thruster

The invention claimed is: 1. A control device for a frequency generator, the control device comprising: a detection unit; and a computing unit; wherein the detection unit is configured to detect a voltage characteristic and current characteristic of a frequency generator and to execute a transmission thereof to the computing unit; wherein the computing unit is configured to determine a temporal offset (Δt 1 , Δt 2 ) between one edge of the current characteristic and an associated edge of the voltage characteristic; wherein the computing unit is configured to generate and vary a switching signal for an output of the voltage characteristic, in order to reduce the temporal offset between one edge of the current characteristic and an associated edge of the voltage characteristic; wherein the detection unit is configured to detect a time point of a zero-crossing in the voltage characteristic and a time point of a zero-crossing in the current characteristic; and wherein the detection unit is configured, further to the detection of a zero-crossing in the voltage characteristic and/or of a zero-crossing in the current characteristic, to suspend any further detection of a zero-crossing in the voltage characteristic and/or of a zero-crossing in the current characteristic for a lock-out time, and only to permit a further detection of a zero-crossing in the voltage characteristic and/or of a zero-crossing in the current characteristic upon the expiry of the lock-out time. 2. The control device as claimed in claim 1 , wherein the detection unit is configured to permit the resumed detection of a zero-crossing in the voltage characteristic and/or of a zero-crossing in the current characteristic further to the expiry of the lock-out time, for the duration of a detection time; and wherein the detection time directly follows the lock-out time and has a duration equal to double a difference between the present cycle time of the voltage characteristic and/or of the current characteristic and a proportion of the lock-out time to which the present cycle time corresponds. 3. The control device as claimed in claim 2 , wherein the detection unit is configured to transmit a zero-crossing which is detected during the detection time to the computing unit; wherein the computing unit is configured, on the basis of the zero-crossing which is detected during the detection time, to redetermine the present cycle time of the current and/or voltage characteristic thus detected; and wherein the computing unit is configured, on the basis of the redetermined cycle time for the detected current and/or voltage characteristic, to redefine the lock-out time and the detection time. 4. The control device as claimed in claim 3 , wherein the redefined lock-out time directly follows the zero-crossing which is detected during the detection time. 5. The control device as claimed in claim 1 , wherein the detection unit comprises a low-pass filter; and wherein the low-pass filter is configured to filter out signal components of the detected current and/or voltage characteristic which exceed a definable frequency threshold value. 6. The control device as claimed in claim 5 , wherein the detection unit is configured to identify the time point of a zero-crossing in the voltage characteristic and/or the time point of a zero-crossing in the current characteristic, subsequently to the filtering of the current and/or voltage characteristic by the low-pass filter. 7. The control device as claimed in claim 1 , wherein the control device comprises a time-delay element; and wherein the time-delay element is configured to add a delay to the time point of a detected zero-crossing in the voltage characteristic and/or a detected zero-crossing in the current characteristic, before the computing unit determines the temporal offset (Δt 1 , Δt 2 ) between one edge of the current characteristic and an associated edge of the voltage characteristic. 8. The control device as claimed in claim 7 , wherein the delay is a phase displacement, which is related to the cycle time of the detected current and/or voltage characteristic. 9. An ion thruster, comprising: a frequency generator for outputting electrical energy at a definable frequency, in order to generate an electric field; and a control device as claimed in claim 1 ; wherein the control device is coupled to the frequency generator, in order to operate the frequency generator at a specified frequency, such that a propellant is ionized in the electric field. 10. The ion thruster as claimed in claim 9 , wherein the frequency generator comprises an oscillating circuit; and wherein the oscillating circuit is a R-L-C oscillating circuit. 11. The ion thruster as claimed in claim 10 , wherein the frequency generator comprises a semiconductor switch mechanism, which is coupled to the oscillating circuit and is configured to actuate the oscillating circuit in accordance with the switching signal of the control device. 12. An ion thruster, comprising: a thruster unit; and a power supply unit having a switch mechanism; wherein the switch mechanism comprises an energy compensation unit; wherein the energy compensation unit is arranged in the switch mechanism on an output side, and is configured to at least partially accommodate a power flashover from the thruster unit to the power supply unit; and wherein the energy compensation unit is configured as a low-capacitance bipolar voltage limiter. 13. The ion thruster as claimed in claim 12 , wherein the energy compensation unit comprises a first branch and a second branch; wherein the first branch comprises a first high-voltage diode and a first suppressor diode which is series-connected and inversely connected thereto; wherein the second branch comprises a second high-voltage diode and a second suppressor diode which is series-connected and inversely connected thereto; wherein the first high-voltage diode is inversely connected to the second high-voltage diode; and wherein the first suppressor diode is inversely connected to the second suppressor diode. 14. An ion thruster, comprising: a thruster unit; and a power supply unit having a switch mechanism; wherein the switch mechanism comprises an adapter unit; wherein the adapter unit comprises a first interface and a second interface; wherein the adapter unit is configured for the take-up of electrical energy from electronic components of the power supply unit via the second interface, and for the output of electrical energy to the thruster unit via the first interface; and wherein the first interface is galvanically isolated from the second interface.