MEMS electrostatic actuator device for RF varactor applications

The invention claimed is: 1. A MEMS electrostatic actuator device, comprising: a CMOS wafer portion having CMOS circuitry; a MEMS wafer portion bonded to the CMOS wafer portion, the MEMS wafer portion having an array of actuator elements formed thereon and a plurality of through-silicon-vias (TSVs) extending through the MEMS wafer portion; and a plurality of ball bonds formed on a side of the MEMS wafer portion opposite the CMOS wafer portion, wherein an RF signal ball bond of the plurality of ball bonds is electrically connected through an RF signal TSV of the plurality of TSVs and an RF signal horizontal feeder bar to a plurality of RF signal lines, wherein the plurality of RF signal lines include one RF signal line extending through each column of the array of actuator elements. 2. The MEMS electrostatic actuator device of claim 1 , further comprising a metal bond ring extending between the CMOS wafer portion and the MEMS wafer portion, the metal bond ring surrounding the array of actuator elements. 3. The MEMS electrostatic actuator device of claim 2 , wherein a GND signal ball bond of the plurality of ball bonds is electrically connected through a GND TSV of the plurality of TSVs and the metal bond ring to the CMOS wafer portion to provide an RF grounding loop. 4. The MEMS electrostatic actuator device of claim 3 , further comprising a ground shield on a side of the CMOS wafer portion facing the MEMS wafer portion, the ground shield extending over the entire array of actuator elements, wherein the ground shield is electrically connected to the metal bond ring and forms part of the RF grounding loop. 5. The MEMS electrostatic actuator device of claim 1 , wherein the MEMS wafer portion includes a higher resistivity substrate relative to the CMOS wafer portion. 6. The MEMS electrostatic actuator device of claim 1 , wherein the CMOS circuitry includes a serial interface controller, a decoder, a charge pump and a DC bias driver. 7. The MEMS electrostatic actuator device of claim 1 , wherein the array of actuator elements are located in a hermetically sealed cavity. 8. The MEMS electrostatic actuator device of claim 1 , wherein the plurality of ball bonds are arranged with all RF ball bonds on outside rows and a GND signal ball bond between adjacent RF ball bonds. 9. The MEMS electrostatic actuator device of claim 1 , wherein each actuator element comprises: a bottom plate having a first electrode for a first RF signal line and a second electrode for a second RF signal line; a pedestal; a top electrode connected to the pedestal, the top electrode having a center membrane portion that extends over the first RF signal line and the second RF signal line; and a pair of cantilever hinges connected between the top electrode and an anchor on opposite ends of the center membrane portion, the pair of cantilever hinges allowing for movement of the center membrane portion closer to and further from the bottom plate. 10. The MEMS electrostatic actuator device of claim 9 , wherein the top electrode has a pair of drive members extending from the center membrane on the opposite ends and wherein each actuator element further comprises a pair of drive out electrodes, each one of the pair of drive out electrodes extending under an associated one of the pair of drive members. 11. The MEMS electrostatic actuator device of claim 10 , wherein each actuator element further includes a pull-in electrode between the first RF signal line and the second RF signal line. 12. A MEMS device, comprising: a CMOS wafer portion having CMOS circuitry; a MEMS wafer portion bonded to the CMOS wafer portion, the MEMS wafer portion having an array of elements formed thereon and a plurality of through-silicon-vias (TSVs) extending through the MEMS wafer portion; and a plurality of ball bonds formed on a side of the MEMS wafer portion opposite the CMOS wafer portion, wherein an RF signal ball bond of the plurality of ball bonds is electrically connected through an RF signal TSV of the plurality of TSVs and an RF signal horizontal feeder bar to a plurality of RF signal lines, wherein the plurality of RF signal lines include one RF signal line extending through each column of the array of elements. 13. The MEMS device of claim 12 , further comprising a metal bond ring extending between the CMOS wafer portion and the MEMS wafer portion, the metal bond ring surrounding the array of elements. 14. The MEMS device of claim 13 , wherein a GND signal ball bond of the plurality of ball bonds is electrically connected through a GND TSV of the plurality of TSVs and the metal bond ring to the CMOS wafer portion to provide an RF grounding loop. 15. The MEMS device of claim 14 , further comprising a ground shield on a side of the CMOS wafer portion facing the MEMS wafer portion, the ground shield extending over the entire array of elements, wherein the ground shield is electrically connected to the metal bond ring and forms part of the RF grounding loop. 16. The MEMS device of claim 12 , wherein the CMOS circuitry includes a serial interface controller, a decoder, a charge pump and a DC bias driver. 17. The MEMS device of claim 12 , wherein the array of elements are located in a hermetically sealed cavity. 18. The MEMS device of claim 12 , wherein the plurality of ball bonds are arranged with all RF ball bonds on outside rows and a GND signal ball bond between adjacent RF ball bonds. 19. The MEMS device of claim 12 , wherein each element comprises: a bottom plate having a first electrode for a first RF signal line and a second electrode for a second RF signal line; a pedestal; a top electrode connected to the pedestal, the top electrode having a center membrane portion that extends over the first RF signal line and the second RF signal line; and a pair of cantilever hinges connected between the top electrode and an anchor on opposite ends of the center membrane portion, the pair of cantilever hinges allowing for movement of the center membrane portion closer to and further from the bottom plate.