Self-tuning external device for wirelessly recharging implantable medical devices

What is claimed is: 1. A method of providing recharge energy from an external device to an implantable medical device where the external device emits the recharge energy from a coil of a tank circuit, comprising: determining when current is changing direction within the tank circuit of the external device due to a resonance of the tank circuit; and driving current through the tank circuit in a first direction without changing the resonance of the tank circuit and based on the determination of when the current in the tank circuit is changing to the first direction due to the resonance of the tank circuit. 2. The method of claim 1 , wherein determining when current is changing direction within the tank circuit comprises allowing current in the tank circuit to flow in a second direction without driving current into the tank circuit while monitoring a voltage at a node of the tank circuit. 3. The method of claim 2 , further comprising detecting when the voltage at the node of the tank circuit changes polarity relative to a ground reference to determine when the current is changing direction. 4. The method of claim 1 , wherein driving current through the tank circuit in the first direction based on determination of when the tank circuit is changing to the first direction comprises activating a first switch to apply voltage from a power supply across the tank circuit. 5. The method of claim 4 , wherein the first switch is a transistor. 6. The method of claim 4 , further comprising deactivating a second switch to prevent a parallel path to a ground reference when activating the first switch. 7. The method of claim 6 , further comprising deactivating the first switch to prevent a parallel path from the voltage source to the tank circuit while allowing current to flow in the second direction. 8. The method of claim 7 , further comprising activating the second switch to provide a path to a ground reference when deactivating the first switch. 9. An external device for interacting with an implantable medical device, comprising: a voltage source; a tank circuit including a coil that emits recharge energy that may be received by the implantable medical device, the tank circuit having a first node and a second node; first and second switches connected to the first node of the tank circuit, the first switch being connected between the voltage source and the first node and the second switch being connected between the first node and the ground reference; a pair of diodes oppositely oriented in parallel between the second node of the tank circuit and a ground reference; and a control circuit connected to the second node of the tank circuit and to the first and second switches to control the state of the switches based on the direction of current flowing in the tank circuit, the control circuit activating the first switch and deactivating the second switch in relation to a first direction of current within the tank circuit and deactivating the first switch and activating the second switch in relation to a second direction of current within the tank circuit. 10. The external device of claim 9 , wherein a polarity of voltage at the second node relative to a ground reference represents the direction of current flowing in the tank circuit and wherein the control circuit detects the polarity of voltage at the second node relative to the ground reference. 11. The external device of claim 10 , wherein the control circuit comprises a comparator having a first input at ground reference and having a second input connected to the second node. 12. The external device of claim 11 , wherein the control circuit further comprises a driver between an output of the comparator and the first switch. 13. The external device of claim 11 , wherein the control circuit further comprises a driver between an output of the comparator and the second switch. 14. The external device of claim 10 , further comprising a multiplexer and a communication controller, the multiplexer connecting the control circuit to the first and second switches during recharge interaction with the implantable medical device and connecting the communication controller to the first and second switches during telemetry interaction with the implantable medical device, the communication controller changing states of the first and second switches during telemetry interaction to cause the coil to emit telemetry signals. 15. The external device of claim 10 , further comprising a telemetry receiver electrically coupled to a node of the tank circuit. 16. A method of providing recharge energy from an external device to an implantable medical device where the external device emits recharge energy from a coil of a tank circuit, comprising: monitoring an electrical characteristic of the tank circuit of the external device during a first phase of a first two-phase cycle while current flows in the tank circuit during the first phase without driving current into the tank circuit during the first phase; and driving current through the tank circuit during a second phase of the first two-phase cycle based on the electrical characteristic being monitored during the first phase to approximate unity power factor during the second phase of the first two-phase cycle without changing a resonance of the tank circuit. 17. The method of claim 16 , wherein the tank circuit has first and second nodes and wherein monitoring the electrical characteristic of the tank circuit comprises monitoring a voltage on a second node of the tank circuit. 18. The method of claim 17 , wherein driving current through the tank circuit during the second phase based on the electrical characteristic being monitored during the first phase comprises driving current through the tank circuit once the voltage on the first node changes polarity relative to a ground reference by applying a voltage to the first node. 19. A medical system, comprising: an implantable medical device; a voltage source; a tank circuit including a coil that emits recharge energy that may be received by the implantable medical device, the tank circuit having a first node and a second node; first and second switches connected to the first node of the tank circuit, the first switch being connected between the voltage source and the first node and the second switch being connected between the first node and the ground reference; a pair of diodes oppositely oriented in parallel between the second node of the tank circuit and a ground reference; and a control circuit connected to the second node of the tank circuit and to the first and second switches to control the state of the switches by monitoring an electrical characteristic of the tank circuit at least during a first phase of a first two-phase cycle while current flows in the tank circuit without current being driven into the tank circuit during the first phase so as to maintain an approximation of unity power factor when driving current from the voltage source into the tank circuit during a second phase of the first two-phase cycle. 20. The medical system of claim 19 , wherein the electrical characteristic is a polarity of voltage at the second node relative to a ground reference. 21. A method of providing recharge energy from an external device to an implantable medical device where the external device emits recharge energy from a coil of a tank circuit, comprising: while maintaining an approximation of unity power factor across the tank circuit of the external device for a driven phase of each