RF filter for an active medical device (AMD) for handling high RF power induced in an associated implanted lead from an external RF field

What is claimed is: 1. A hermetically sealed feedthrough filter assembly for an implantable medical device, the feedthrough filter assembly comprising: a) an electrically conductive ferrule defining a ferrule opening, wherein the ferrule is configured to be attachable to an opening in a housing of an active implantable medical device; b) an insulator at least partially residing in the ferrule opening where a hermetic seal connects the insulator to the ferrule, wherein the insulator extends from an insulator body fluid side to an insulator device side with an insulator via hole extending through the insulator to the insulator body fluid and device sides; c) a conductive pathway hermetically sealed to the insulator in the via hole, the conductive pathway extending from a conductive pathway body fluid side to a conductive pathway device side, wherein the conductive pathway is in a non-conductive relation with the ferrule; d) a filter capacitor, comprising: i) a ceramic dielectric body having a dielectric constant that is greater than zero, but less than 1,000; and ii) at least two active electrode plates interleaved with at least two ground electrode plates supported in the ceramic dielectric body; e) a first conductive structure electrically connecting the at least two active electrode plates to the conductive pathway device side; and f) a second conductive structure electrically connecting the at least two ground electrode plates to the ferrule, g) wherein the filter capacitor has: i) a capacitance that ranges from 10 and 20,000 picofarads, and ii) an equivalent series resistance (ESR), which is the sum of a dielectric loss plus an ohmic loss of the ceramic dielectric body, that is greater than zero, but less than 2.0 ohms at an MRI RF pulsed frequency or at a range of MRI RF pulsed frequencies, h) wherein the filter capacitor is the first filter capacitor electrically connected to the conductive pathway device side and to the ferrule. 2. The feedthrough filter assembly of claim 1 , wherein the filter capacitor is selected from the group consisting of a monolithic ceramic feedthrough filter capacitor, a flat-through capacitor, an MLCC chip capacitor, and an X2Y attenuator. 3. The feedthrough filter assembly of claim 1 , wherein the filter capacitor is a multi-element broadband lowpass filter having at least one inductor, the multi-element broadband lowpass filter forming one of the group consisting of an L-filter, a reverse L-filter, an LL-filter, a reverse LL-filter, a T-filter, a Pi-filter, and an n-element lowpass filter. 4. The feedthrough filter assembly of claim 1 , wherein the filter capacitor has a dielectric loss tangent measured in ohms that is greater than zero, but less than five percent of the ESR of the filter capacitor at the MRI RF pulsed frequency or at the range of MRI RF pulsed frequencies. 5. The feedthrough filter assembly of claim 1 , wherein the filter capacitor is a passive component lowpass filter. 6. The feedthrough filter assembly of claim 1 , wherein the MRI RF pulsed frequency is 64 MHz or 128 MHz or the MRI RF pulsed frequency is a range of frequencies centered at 64 MHz or 128 MHz. 7. The feedthrough filter assembly of claim 1 , wherein the capacitance of the filter capacitor ranges from 350 to 10,000 picofarads. 8. The feedthrough filter assembly of claim 1 , wherein the ESR of the filter capacitor at the MRI RF pulsed frequency or at the range of MRI RF pulsed frequencies is greater than zero, but less than 0.5 ohms. 9. The feedthrough filter assembly of claim 1 , wherein the ESR of the filter capacitor at the MRI RF pulsed frequency or at the range of MRI RF pulsed frequencies is greater than zero, but less than 0.1 ohms. 10. The feedthrough filter assembly of claim 1 , wherein ceramic dielectric body of the filter capacitor supports at least ten active electrode plates interleaved with at least ten ground electrode plates. 11. The feedthrough filter assembly of claim 1 , including an insulative washer disposed between the filter capacitor and the insulator or the ferrule or, between the filter capacitor and both the insulator and the ferrule. 12. The feedthrough filter assembly of claim 1 , wherein the conductive pathway is selected from a conductive wire, a platinum fill, and a conductive paste, and combinations thereof, the platinum fill and conductive paste characterized as having been co-fired with an alumina ceramic serving as the insulator. 13. The feedthrough filter assembly of claim 12 , wherein the at least one conductive wire comprises a circuit trace. 14. The feedthrough filter assembly of claim 13 , including at least one diode disposed between the conductive pathway device side and the at least two active electrode plates, wherein a first diode end is electrically connected to the conductive pathway device side and a second diode end is electrically connected to the ferrule. 15. The feedthrough filter assembly of claim 14 , wherein the at least one diode comprises back-to-back diodes. 16. The feedthrough filter assembly of claim 13 , including a diode or back-to-back diodes electrically connected in parallel with the filter capacitor. 17. The feedthrough filter assembly of claim 1 , wherein the first conductive structure comprises a first metallization contacting the at least two active electrode plates and an electrically conductive material connecting from the first metallization to the conductive pathway device side. 18. The feedthrough filter assembly of claim 1 , wherein the second conductive structure comprises a second metallization contacting the at least two ground electrode plates and at least one of the group consisting of a solder, a braze, a thermal-setting conductive material, and a conductive polyimide connecting from the second metallization to either the ferrule or the conductive housing or, to both the ferrule and the conductive housing. 19. The feedthrough filter assembly of claim 1 , wherein a gold braze hermetically seals from an outer surface of the insulator to the ferrule. 20. An active implantable medical device (AIMD), comprising: a) a conductive housing defining a body fluid side and a device side, wherein the body fluid side is located outside the conductive housing and the device side is located inside the conductive housing; b) an electrically conductive ferrule sealed in a housing opening in the conductive housing, the ferrule having a ferrule opening extending from a ferrule body fluid side to a ferrule device side; c) an insulator at least partially residing in the ferrule opening where a hermetic seal connects the insulator to the ferrule, wherein the insulator comprises at least one insulator via hole extending from a via body fluid side to a via device side; d) a conductive pathway hermetically sealed to the insulator in the via hole, the conductive pathway extending from a conductive pathway body fluid side to a conductive pathway device side, wherein the conductive pathway is in a non-conductive relation with the ferrule and the conductive housing; e) a filter capacitor located inside the conductive housing and comprising: i) a ceramic dielectric body having a dielectric constant that is greater than zero, but less than 1,000; and ii) at least two active electrode plates interleaved with at least two ground electrode plates supported in the ceramic dielectric body; f) a first conductive structure electrically connecting the at least two active electrode plates to the conductive pathway device side; and g) a second co