Dynamic damper in an X-ray system

The invention claimed is: 1. An X-ray generator comprising: a high voltage generator operable to provide an output voltage to an X-ray tube; and a dynamic damper with a frequency dependent impedance in communication with a cathode of the X-ray tube and the high voltage generator. 2. The X-ray generator of claim 1 , wherein the dynamic damper is a solenoid. 3. The X-ray generator of claim 2 , wherein the solenoid is constructed of magnetic stainless steel wire windings. 4. The X-ray generator of claim 3 , wherein the impedance of the dynamic damper comprises an inductance of the solenoid that increases with frequency and a resistance of the magnetic stainless steel wire windings that increases with frequency. 5. The X-ray generator of claim 1 , wherein at a frequency less than 50 kHz the dynamic damper provides an impedance less than ⅓ of a reference impedance needed to protect the high voltage generator. 6. The X-ray generator of claim 5 wherein at the frequency less than 50 kHz, the dynamic damper provides an impedance less than 1/10 of the reference impedance needed to protect the high voltage generator. 7. The X-ray generator of claim 5 , wherein at frequencies above 5 MHz the dynamic damper provides an impedance greater than the reference impedance needed to protect the high voltage generator. 8. The X-ray generator of claim 5 , wherein the reference impedance is between 500 Ohms and 15,000 Ohms. 9. The X-ray generator of claim 1 , further comprising a distributed resonant energy recovery (DRER) circuit comprising: at least one capacitor; and a plurality of switches arranged in series to the at least one capacitor, the switches operable to selectively store energy in the at least one capacitor, wherein the high voltage generator is operable to provide output voltages to the X-ray tube at a first kV level and at a second kV level, the second kV level higher than the first kV level, and when the high voltage generator provides an output voltage to the X-ray tube at the first kV level, the energy is received and stored in the at least one capacitor, and when the high voltage generator provides an output voltage to the X-ray tube at the second kV level, energy is discharged from the at least one capacitor to achieve the second kV level. 10. The X-ray generator of claim 9 , further comprising: a high voltage cable arranged between the high voltage generator and the X-ray tube wherein when the high voltage generator is operated to provide the second kV level to the X-ray tube, energy is stored in a capacitance of the high voltage cable, and when the high voltage generator is operated to provide the first kV level to the X-ray tube, the high voltage cable is discharged through the dynamic damper to the DRER circuit to store energy in the at least one capacitor of the DRER circuit. 11. The X-ray generator of claim 1 , further comprising: a high voltage tank wherein the dynamic damper is located inside of the high voltage tank. 12. A method of protecting against tube-spit in an X-ray generator, the method comprising: supplying an X-ray tube with a high voltage potential from a high voltage tank assembly with a transformer; interposing a dynamic damper between a cathode of the X-ray tube and the transformer, wherein the dynamic damper provides a frequency variable impedance; providing a first impedance of the dynamic damper while supplying the X-ray tube with the high voltage potential; and providing a second impedance of the dynamic damper upon occurrence of tube-spit within the X-ray tube, wherein the second impedance is greater than the first impedance. 13. The method of claim 12 , further comprising: selectively providing a first kV level to the X-ray tube from the high voltage tank assembly; and selectively providing a second kV level to the X-ray tube from the high voltage tank assembly; wherein the second kV level is greater than the first kV level. 14. The method of claim 13 , wherein the high voltage tank assembly further comprises a plurality of switching devices and at least one capacitor arranged in series to the plurality of switching devices, the plurality of switching devices operable to selectively store and release energy from the at least one capacitor, the method further comprising: operating the high voltage tank assembly to provide the first kV level to the X-ray tube; receiving and storing energy in the at least one capacitor; operating the high voltage tank assembly to provide the second kV level to the X-ray tube; and discharging the at least one capacitor to facilitate switching from the first kV level to the second kV level. 15. The method of claim 14 , further comprising: receiving energy through the dynamic damper; and storing the received energy in the at least one capacitor. 16. The method of claim 15 , wherein at a frequency less than 50 kHz the dynamic damper has an impedance less than ⅓ of a reference impedance needed to protect a voltage rectifier and the transformer in the high voltage tank assembly, tube-spit within the X-ray tube occurs at a frequency greater than 10 MHz, and wherein the impedance of the dynamic damper increases exponentially at a frequency above 50 kHz to an impedance greater than the reference impedance. 17. The method of claim 15 , wherein a high voltage cable is arranged between the high voltage tank assembly and the X-ray tube, and wherein when the high voltage tank assembly is operated to provide the second kV level to the X-ray tube, energy is stored in the high voltage cable, and when the high voltage tank assembly is operated to provide the first kV level to the X-ray tube, the high voltage cable is discharged through the dynamic damper to store energy in the at least one capacitor. 18. A high voltage tank assembly in an X-ray generator comprising: a transformer assembly configured to receive high frequency input power; a voltage rectifier coupled to the transformer assembly and configured to receive an input voltage from the transformer assembly and provide an output voltage to an X-ray tube; and a dynamic damper with a frequency dependent impedance interposed between the X-ray tube and the voltage rectifier, wherein the impedance of the dynamic damper increases with an increase in frequency. 19. The high voltage tank assembly of claim 18 , further comprising a distributed resonant energy recovery (DRER) circuit comprising: at least one capacitor; and a plurality of switching devices arranged in series to the at least one capacitor, the switches operable to selectively store energy in the at least one capacitor, wherein the voltage rectifier is configured to provide output voltages to the X-ray tube at a first kV level and at a second kV level, the second kV level higher than the first kV level, and when an output voltage is provided to the X-ray tube at the first kV level, energy is received and stored in the at least one capacitor, and when an output voltage is provided to the X-ray tube at the second kV level, energy is discharged from the at least one capacitor to achieve the second kV level. 20. The high voltage tank assembly of claim 18 , wherein the voltage rectifier is a full bridge rectifier or a voltage doubler.