Recharge tuning techniques for an implantable device

What is claimed is: 1. A charging system configured to transcutaneously deliver power, comprising: a primary coil; a drive circuit configured to drive the primary coil at a drive frequency; and a control circuit configured to tune the drive frequency based on a characteristic of a signal that occurs within the primary coil wherein the signal has a signal level that varies with respect to time, wherein the characteristic is not present when the primary coil is being driven at a resonant frequency of the system and wherein the characteristic comprises at least one transition in the signal level of the signal. 2. The charging system of claim 1 , further comprising an edge detect circuit configured to detect the characteristic. 3. The charging system of claim 1 , wherein the control circuit is configured to change the drive frequency based on relative timing between the characteristic and another characteristic of the signal. 4. The charging system of claim 1 , wherein the characteristic comprises a stub pulse, and wherein the control circuit is configured to decrease the drive frequency if the stub pulse appears within a predetermined time period of another characteristic of the signal and otherwise the control circuit is configured to increase the frequency of the signal. 5. The charging system of claim 1 , wherein the drive circuit comprises an H-bridge circuit. 6. The charging system of claim 1 , wherein the control circuit is configured to increase a duty cycle at which the primary coil is being driven until the characteristic first appears in the signal at a first frequency, to adjust the drive frequency until the characteristic disappears and reappears at a second frequency, and to adjust the drive frequency to be the average of the first and the second frequencies. 7. The charging system of claim 1 , wherein the control circuit is configured to monitor the characteristic of the signal to determine a location at which to position the primary coil to transcutaneously deliver power. 8. The charging system of claim 1 , further comprising a detection circuit to detect the characteristic, the detection circuit being coupled to a circuit node associated with the primary coil that is not being driven at a time when the characteristic occurs. 9. The system of claim 1 , further comprising: a cable coupled to the primary coil; and wherein the control circuit is carried by the cable. 10. The system of claim 1 , further comprising: an implantable medical device (IMD) configured to receive the transcutaneously-delivered power; and a programmer configured to exchange at least one of data and programmed instructions with the IMD, and wherein the programmer comprises, or is communicatively coupled to, the control circuit. 11. The charging system of claim 1 , further comprising a tank circuit comprising the primary coil, and wherein the signal is a signal detected in the tank circuit. 12. A charging system configured to transcutaneously deliver power, comprising: a primary coil; a drive circuit configured to drive the primary coil at a drive frequency; and a control circuit configured to tune the drive frequency based on a characteristic of a signal that is associated with the primary coil, wherein the characteristic is not present when the primary coil is being driven at a resonant frequency of the system, wherein the characteristic comprises a stub pulse, and wherein the control circuit is configured to change the drive frequency by an amount that is based on a width of the stub pulse. 13. A charging system configured to transcutaneously deliver power, comprising: a primary coil; a drive circuit configured to drive the primary coil at a drive frequency; and a control circuit configured to tune the drive frequency based on a characteristic of a signal that is associated with the primary coil, wherein the characteristic is not present when the primary coil is being driven at a resonant frequency of the system and wherein the control circuit is configured to determine a high frequency at which the characteristic first appears in the signal and a low frequency at which the characteristic first appears in the signal, and to adjust the drive frequency to be the average of the high and the low frequencies. 14. A charging system configured to transcutaneously deliver power, comprising: a primary coil; a drive circuit configured to drive the primary coil at a drive frequency; and a control circuit configured to tune the drive frequency based on a characteristic of a signal that is associated with the primary coil, wherein the characteristic is not present when the primary coil is being driven at a resonant frequency of the system and wherein the control circuit is configured to adjust the drive frequency until the characteristic disappears at a first frequency and reappears at a second frequency, and to adjust the drive frequency to be the average of the first and second frequencies. 15. A charging system configured to transcutaneously deliver power, comprising: a primary coil; a drive circuit configured to drive the primary coil at a drive frequency; and a control circuit configured to tune the drive frequency based on a characteristic of a signal that is associated with the primary coil, wherein the characteristic is not present when the primary coil is being driven at a resonant frequency of the system, wherein the drive circuit is configured to enforce a dead period during which the primary coil is not being driven and wherein the characteristic occurs during the dead period. 16. A system, comprising: a circuit configured to generate a signal associated with transcutaneously delivering power, and to tune the signal to a resonant frequency of the system based on a characteristic in the signal that is not present when the signal is at the resonant frequency of the system, wherein the characteristic comprises a negative-to-positive-going or a positive-to-negative-going transition. 17. The system of claim 16 , wherein the circuit is configured to adjust the frequency of the signal based on relative timing between the characteristic in the signal that is not present when the signal is at the resonant frequency of the system and a characteristic of the signal that is present when the signal is at the resonant frequency of the system. 18. The system of claim 17 , wherein the negative-to-positive-going or the positive-to-negative-going transition comprises multiple different amplitude levels. 19. The system of claim 16 , wherein the characteristic in the signal that is not present when the signal is at the resonant frequency of the system comprises a stub pulse. 20. The system of claim 16 , wherein the circuit is configured to automatically tune the signal based on a predetermined trigger event occurring while transcutaneously delivering power. 21. The system of claim 16 , further comprising an implantable medical device to receive the transcutaneously delivered power. 22. A method of transcutaneously delivering power, comprising: driving a primary coil; monitoring a signal that occurs within the primary coil; detecting a transition in the monitored signal, the transition occurring with respect to time; and adjusting a drive signal that is driving the primary coil to a resonant frequency based on a characteristic in the monitored signal that is not present when the drive signal is at the resonant frequency, wherein the characteristic comprises the detected transition.