Digitally timed CMOS rectifier for wireless power transfer

What is claimed is: 1. A voltage rectification circuit for a medical device having an internal coil and internal circuitry, the voltage rectification circuit comprising: a rectifier having actively driven low-side first type transistors and cross-coupled second type transistors, a first type being one of N-type and P-type and a second type being an opposite one of the N-type and P-type, each low-side first-type transistor being configured with a first type diode; the rectifier configured to receive a time varying periodic voltage from the internal coil and to output a rectified received voltage, the actively driven first type transistors being further configured to receive an enable signal to cause the rectifier to switch between rectifier states; a comparator configured to detect when the received time varying voltage crosses a voltage threshold, the voltage threshold being sufficiently low to enable each actively driven first type transistor to conduct through the first type diode; digital timing circuitry configured to: estimate windows of time for which the received time varying voltage can be expected to conduct through the first type diodes; and generate the enable signal to enable each actively driven first type transistor to conduct through a channel of the actively driven first type transistor while bypassing conduction through the first type diode. 2. The voltage rectification circuit of claim 1 , wherein the cross-coupled second type transistors and the actively driven first type transistors are referenced to ground and the enable signal is referenced to ground. 3. The voltage rectification circuit of claim 1 , further comprising a digital communication circuit configured to receive a synchronization signal from the digital timing circuitry and to provide a clock to modulate a load. 4. The voltage rectification circuit of claim 3 , wherein timing signals to modulate the load are only provided when a rectifier output is activated. 5. The voltage rectification circuit of claim 1 , wherein the first window of time is estimated based at least in part on a first load, and a second window of time is estimated based at least in part on a second load, the first window of time being subsequent to the first window of time. 6. The voltage rectification circuit of claim 5 , wherein the rectifier switching occurs without monitoring a rectifier input voltage when switching of load capacitances is enabled. 7. The voltage rectification circuit of claim 1 , wherein the rectifier is active when the actively driven first type transistors are enabled to conduct through respective actively driven first type transistor channels. 8. The voltage rectification circuit of claim 1 , wherein a duration of a first window of time is adjusted to maximize a time that an AC coil voltage is above zero volts. 9. The voltage rectification circuit of claim 1 , wherein the enable signal is applied to a gate of an actively driven first type transistor. 10. The voltage rectification circuit of claim 1 , wherein the received time varying voltage is applied between an actively driven first type transistor and a cross-coupled second type transistor. 11. A voltage rectification circuit for a medical device having an internal coil and internal circuitry, the voltage rectification circuit comprising: a voltage rectifier comprising a complementary metal oxide semiconductor (CMOS) circuit having low-side first type MOS transistors and upper cross-coupled second type MOS transistors, a first type being one of N-type and P-type and a second type being an opposite one of the N-type and P-type, the voltage rectifier configured to receive a time varying periodic voltage from the internal coil and to output a rectified received voltage, each low-side first type MOS transistor being configured with a first type MOS body diode, the low-side first type MOS transistors being enabled by a timing signal to provide conduction through the low-side first type MOS transistors while bypassing conduction through the first type MOS body diode during a time window having a duration determined by voltage level crossings of the received time varying voltage, a voltage level being a threshold voltage; and digital timing circuitry configured to provide the timing signal; the timing signal being based on the voltage level crossings. 12. The voltage rectification circuit of claim 11 , wherein the low-side first type MOS transistors are referenced to ground. 13. The voltage rectification circuit of claim 11 , wherein the duration of the time window increases when a load of the medical device increases and decreases when a load of the medical device decreases. 14. The voltage rectification circuit of claim 11 , wherein the digital timing circuitry is further configured to provide a synchronization signal to synchronize modulation of a load of a communication capacitance so that the communication capacitance is modulated only when a voltage on the communication capacitance is zero volts. 15. The voltage rectification circuit of claim 14 , wherein the load modulation encodes information to be transmitted from the internal circuitry via the internal coil to a power transmitter to enable closed loop regulation of power delivered by the power transmitter to the internal coil. 16. The voltage rectification circuit of claim 11 , wherein the voltage rectifier is active during the time window. 17. The voltage rectification circuit of claim 11 , wherein the duration of the time window is adjusted to minimize a time of a voltage level being below zero volts. 18. The voltage rectification circuit of claim 11 , wherein the digital timing circuitry causes load switching to occur without monitoring a rectifier input voltage when switching of a capacitive load is enabled. 19. The voltage rectification circuit of claim 11 , wherein the timing signal is applied to a gate of a low-side first type MOS transistor. 20. The voltage rectification circuit of claim 11 , wherein the received time varying voltage is applied between a low-side first type MOS transistor and an upper cross-coupled second type MOS transistor.