Temperature sensing of implanted wireless recharge coil

What is claimed is: 1 . A transcutaneous energy transfer system (TETS), comprising: an implantable controller including an internal power supply, the implantable controller configured to be implanted at a first location within a patient; an implantable receiving coil configured to be implanted at a second location within a patient that is separate from the first location, the implantable receiving coil electrically coupled to the implantable controller by a cable, wherein the implantable receiving coil is configured to be inductively powered through the patient's skin by an external transmission coil disposed on the outside/exterior of the patient's body and to electrically recharge the internal power supply of the implantable controller through the cable while the implantable receiving coil is being inductively powered; and a hermetically sealed package in contact with the implantable receiving coil and coupled to the implantable controller by the cable, the hermetically sealed package including: a plurality of tuning capacitors; at least one temperature sensor, the at least one temperature sensor being configured to measure a temperature of the hermetically sealed package; scavenging circuitry being configured to scavenge power from the plurality of tuning capacitors to power a temperature measuring circuit; and the temperature measuring circuit connected to the at least one temperature sensor and the scavenging circuitry, wherein the temperature measuring circuit is configured to transmit the temperature measured by the at least one temperature sensor to the implantable controller through the cable. 2 . The TETS of claim 1 , wherein the implantable receiving coil is configured for transcutaneous inductive communication with the external transmission coil. 3 . The TETS of claim 2 , wherein the temperature of the hermetically sealed package measured by the at least one temperature sensor is indicative of a degree of alignment between the implantable receiving coil and the external transmission coil. 4 . The TETS of claim 1 , wherein the temperature measuring circuit is further configured to transmit through the cable the temperature measured by the at least one temperature sensor on an RF modulated carrier signal. 5 . The TETS of claim 4 , wherein a frequency of the RF modulated carrier signal is higher than a power transfer frequency between the implantable receiving coil and the external transmission coil. 6 . The TETS of claim 1 , further including an external controller in communication with the external transmission coil, the implantable controller being configured to perform at least one operation selected from a group including reducing battery charging, disabling battery charging, and transmitting an alert to the external controller when the temperature measured by the at least one temperature sensor of the hermetically sealed package exceeds a predetermined threshold temperature. 7 . The TETS of claim 6 , wherein the predetermined threshold temperature is a temperature between 43° C. and 65° C. 8 . The TETS of claim 6 , wherein the alert is at least one selected from a group including an audible alert notification, a visual alert notification, and a tactile alert notification to correct a degree of alignment between the implantable receiving coil and the external transmission coil. 9 . The TETS of claim 6 , wherein the implantable controller is configured to transmit the alert to the external controller via a Bluetooth signal. 10 . The TETS of claim 1 , wherein the hermetically sealed package is composed of at least one selected from a group including titanium, glass, sapphire, and ceramic materials. 11 . The TETS of claim 1 , wherein the internal power supply of the implantable controller is configured to provide electrical power to one or more implantable medical devices through one or more implanted conductors, the one or more implantable medical devices positioned at one or more implant locations that are different from both the first location and the second location. 12 . A transcutaneous energy transfer system (TETS), comprising: an external transmission coil in communication with an external controller; an implantable controller including an internal power supply, the implantable controller configured to be implanted at a first location within a patient; an implantable receiving coil configured to be implanted at a second location within a patient that is separate from the first location, the implantable receiving coil electrically coupled to the implantable controller by a cable, wherein the implantable receiving coil is configured to be inductively powered through the patient's skin by the external transmission coil disposed on the outside/exterior of the patient's body and to electrically recharge the internal power supply of the implantable controller through the cable while the implantable receiving coil is being inductively powered; and a hermetically sealed package in contact with the implantable receiving coil and coupled to the implantable controller by the cable, the hermetically sealed package including: a plurality of tuning capacitors; at least one temperature sensor, the at least one temperature sensor being configured to measure a temperature of the hermetically sealed package; scavenging circuitry being configured to scavenge power from the plurality of tuning capacitors to power a temperature measuring circuit; and the temperature measuring circuit in communication with the at least one temperature sensor and the scavenging circuitry, wherein the temperature measuring circuit is configured to transmit the temperature measured by the at least one temperature sensor to the implantable controller through the cable. 13 . The TETS of claim 12 , wherein the temperature of the hermetically sealed package measured by the at least one temperature sensor is indicative of a degree of alignment between the implantable receiving coil and the external transmission coil. 14 . The TETS of claim 12 , wherein the temperature measuring circuit is further configured to transmit through the cable the temperature measured by the at least one temperature sensor on an RF modulated carrier signal. 15 . The TETS of claim 14 , wherein a frequency of the RF modulated carrier signal is higher than a power transfer frequency between the implantable receiving coil and an external transmission coil. 16 . The TETS of claim 12 , wherein the implantable controller is configured to perform at least one operation selected from the group consisting of: reducing battery charging, disabling battery charging, and transmitting an alert to the external controller when the temperature measured by the at least one temperature sensor of the hermetically sealed package exceeds a predetermined threshold temperature. 17 . The TETS of claim 16 , wherein the predetermined threshold temperature is a temperature between 43° C. and 65° C. 18 . The TETS of claim 16 , wherein the alert is at least one selected from a group including an audible alert notification, a visual alert notification, and a tactile alert notification to correct a degree of alignment between the implantable receiving coil and the external transmission coil while the implantable receiving coil is being inductively powered by the external transmission coil. 19 . The TETS of claim 12 , wherein the internal power supply of the implantable controller is configured to provide electrical power to one or more implantable medical devices through on