Integrated implantable TETS housing including fins and coil loops

What is claimed is: 1. An implantable TET receiver unit, comprising: an internal housing; an energy source disposed in the internal housing; a controller disposed in the internal housing, the controller configured to control operation of the TET receiver; a ferrite housing disposed around the internal housing, the ferrite housing configured to reduce an amount of magnetic flux that reaches the internal housing; and at least one wire coil wrapped around the ferrite housing and electrically coupled to the controller, the at least one wire coil configured to receive wireless energy from an external power transmitter. 2. The TET receiver unit of claim 1 , wherein the ferrite housing comprises two ferrite halves machined out of solid pieces of ferrite. 3. The TET receiver unit of claim 1 , wherein the ferrite housing comprises a plurality of ferrite tiles. 4. The TET receiver unit of claim 1 , further comprising at least one ferrite fin extending from the ferrite housing and positioned next to the at least one wire coil. 5. The TET receiver unit of claim 4 , wherein the at least one ferrite fin extends around at least a portion of a perimeter of the ferrite enclosure. 6. The TET receiver unit of claim 4 , wherein the at least one ferrite fin extends around a perimeter of the ferrite enclosure. 7. The TET receiver unit of claim 1 , wherein the at least one wire coil further comprises at least one exciter coil and at least one resonator coil. 8. The TET receiver unit of claim 6 , further comprising a first ferrite fin extending from the ferrite enclosure and positioned between the at least one resonator coil and an external wireless power transmitter, and second ferrite fin extending from the ferrite enclosure and positioned between the resonator coil and the exciter coil, and a third ferrite fin extending from the ferrite enclosure and positioned on an opposite side of the exciter coil from the second ferrite fin. 9. The TET receiver unit of claim 4 , wherein the at least one ferrite fin is configured to increase a coupling between the at least one wire coil and an external wireless power transmitter. 10. The TET receiver unit of claim 4 , wherein the at least one ferrite fin is configured to decrease a coupling between a resonator coil and an exciter coil of the at least one wire coil. 11. The TET receiver unit of claim 1 , wherein a ferrite gap between the ferrite housing occurs along small sides of the internal housing. 12. The TET receiver unit of claim 1 , wherein a ferrite gap between the ferrite housing occurs along large sides of the internal housing. 13. A system for wireless energy transfer, comprising: a transmitter unit comprising a transmitter resonator coil coupled to a power supply and configured to transmit wireless energy; and a receiver unit comprising an internal housing, an energy source disposed in the internal housing, a controller disposed in the internal housing, the controller configured to control operation of the TET receiver, a ferrite housing disposed around the internal housing, the ferrite housing configured to reduce an amount of magnetic flux that reaches the internal housing, and at least one wire coil wrapped around the ferrite housing and electrically coupled to the controller, the at least one wire coil configured to receive wireless energy from the transmitter unit. 14. The system of claim 13 , further comprising at least one ferrite fin extending from the ferrite housing and positioned next to the at least one wire coil. 15. The system of claim 14 , wherein the at least one ferrite fin extends around a perimeter of the ferrite enclosure. 16. The system of claim 13 , wherein the at least one wire coil further comprises at least one exciter coil and at least one resonator coil. 17. The system of claim 14 , wherein the at least one ferrite fin is configured to increase a coupling between the at least one wire coil and the transmitter unit. 18. The system of claim 14 , wherein the at least one ferrite fin is configured to decrease a coupling between a resonator coil and an exciter coil of the at least one wire coil. 19. An implantable TET receiver unit, comprising: an internal housing; an energy source disposed in the internal housing; a controller disposed in the internal housing, the controller configured to control operation of the TET receiver; and a coil structure sized and configured to be placed around the internal housing, the coil structure including at least one wire coil configured to receive wireless energy from an external power transmitter, the coil structure further including at least one ferrite strip disposed near the at least one wire coil and configured to increase a coupling between the at least one coil structure and the external power transmitter. 20. A method of transmitting and receiving wireless energy, comprising: transmitting wireless energy from a transmitter coil into a patient; receiving the wireless energy with a wire coil of a receiver unit implanted in the patient, the wire coil wrapped around a ferrite enclosure that houses electronics of the receiver unit; and preventing magnetic flux from interfering with the electronics of the receiver unit with the ferrite enclosure. 21. A method of transmitting and receiving wireless energy, comprising: transmitting wireless energy from a transmitter coil into a patient; receiving the wireless energy with a wire coil of a receiver unit implanted in the patient, the wire coil wrapped around a ferrite enclosure that houses electronics of the receiver unit; and increasing a coupling between the transmitter coil and the receiver unit with a ferrite fin of the ferrite enclosure that is disposed near the wire coil. 22. The TET receiver unit of claim 1 , further comprising an integrated antenna disposed on or near the internal housing and electrically coupled to the controller. 23. The TET receiver unit of claim 22 , wherein the integrated antenna is formed on a wall of the ferrite housing. 24. The TET receiver unit of claim 23 , further comprising a polymer encapsulating the ferrite housing, the internal housing, and the integrated antenna.