System and method for driving an ultrasonic handpiece with a linear amplifier

What is claimed is: 1. A control console for supplying an AC drive signal to a driver of an ultrasonic handpiece to vibrate a tip of the ultrasonic handpiece, the control console comprising: a transformer including a primary winding having first and second opposed ends and a center tap to which a DC voltage is applied, and including a secondary winding across which the AC drive signal is developed for vibrating the tip of the ultrasonic handpiece; and first and second transistors functioning as first and second active resistors coupled to the first and second opposed ends of the primary winding respectively for developing an AC voltage across the primary winding, wherein the control console is configured to vary a level of the DC voltage applied to the center tap of the primary winding based on the AC voltage developed across the primary winding. 2. The control console of claim 1 , further comprising a processor configured to: determine a voltage across the first and second transistors that relates to the AC voltage developed across the primary winding; and set the level of the DC voltage applied to the center tap of the primary winding based on the determined voltage. 3. The control console of claim 1 , further comprising: a headroom monitor coupled to the first and second transistors and configured to generate a headroom signal representative of a voltage across the first and second transistors that relates to the AC voltage developed across the primary winding; and a processor coupled to the headroom monitor and configured to set the level of the DC voltage applied to the center tap of the primary winding based on the headroom signal. 4. The control console of claim 3 , wherein the headroom monitor is configured to receive as inputs voltages at first ends of the first and second transistors and voltages at second ends of the first and second transistors that are opposite the first ends, and to generate the headroom signal based on a difference between the lower of the voltages present at the first ends of the first and second transistors and the higher of the voltages present at the second ends of the first and second transistors. 5. The control console of claim 3 , wherein the headroom monitor is constructed so that voltages present between the first and second transistors and the transformer primary winding are applied to separate reverse biased diodes, the anodes of the reverse biased diodes are connected at a junction, and a constant voltage is applied to the junction of the anodes so that the voltage present at the junction of the anodes is the lower of the voltages present between the first and second transistors and the transformer primary winding, and wherein the headroom monitor is configured to generate the headroom signal based on the voltage present at the junction of the anodes. 6. The control console of claim 5 , wherein the headroom monitor is constructed so that voltages present at ends of the first and second transistors that are distal to the transformer primary winding are applied to separate forward biased diodes, the cathodes of the forward biased diodes are connected at a junction, and the voltage present at the junction of the cathodes is the higher of the voltages at the ends of the first and second transistors, and wherein the headroom monitor is configured to generate the headroom signal based on the voltage present at the junction of the cathodes. 7. The control console of claim 3 , wherein the processor is configured to: determine a change in voltage to be developed across the primary winding; and set the level of the DC voltage applied to the center tap of the primary winding based on the determined change in voltage and the headroom signal. 8. The control console of claim 7 , further comprising: a sensor for measuring a voltage of the AC drive signal supplied to the ultrasonic handpiece; and a sensor for measuring a current of the AC drive signal supplied to the ultrasonic handpiece, wherein the processor is configured to determine the change in voltage to be developed across the primary winding based on the measured voltage and current of the AC drive signal. 9. The control console of claim 7 , wherein the processor is configured to determine the change in voltage to be developed across the primary winding based on the headroom signal. 10. The control console of claim 7 , wherein the processor is configured to: determine an adjusted headroom voltage based on the headroom signal and the determined change in voltage to be developed across the primary winding; compare the adjusted headroom voltage to a target headroom voltage; and set the level of the DC voltage applied to the center tap of the primary winding based on the comparison. 11. The control console of claim 7 , wherein the processor is configured to: determine whether the AC voltage developed across the primary winding is to decrease based on the determined change in voltage; and responsive to determining that the AC voltage developed across the primary winding is to decrease, prevent the level of the DC voltage applied to the center tap of the primary winding from being lowered for at least a set period. 12. The control console of claim 7 , wherein the processor is configured to: determine whether the AC voltage developed across the primary winding is to decrease based on the determined change in voltage; and responsive to determining that the AC voltage developed across the primary winding is to decrease, lower the level of the DC voltage applied to the center tap of the primary winding at a first rate that is slower than a second rate at which the AC voltage developed across the primary winding is decreased. 13. The control console of claim 10 , wherein the processor is configured to adjust the target headroom voltage for comparison with the adjusted headroom voltage based on a voltage of the AC drive signal. 14. The control console of claim 12 , wherein the processor is configured to: determine whether the AC voltage developed across the primary winding is to increase based on the determined change in voltage; and responsive to determining that the AC voltage developed across the primary winding is to increase, raise the level of the DC voltage at a third rate that is faster than the first rate. 15. A control console for supplying an AC drive signal to a driver of an ultrasonic handpiece to vibrate a tip of the ultrasonic handpiece, the control console comprising: a transformer including a primary winding having first and second opposed ends and a center tap to which a DC voltage is applied, and including a secondary winding across which the AC drive signal is developed for vibrating the tip of the ultrasonic handpiece; first and second transistors functioning as first and second active resistors coupled to the first and second opposed ends of the primary winding respectively for developing an AC voltage across the primary winding; and a processor configured to: determine a change in voltage to be developed across the primary winding; and vary a level of the DC voltage applied to the center tap of the primary winding based on the determined change in voltage. 16. The control console of claim 15 , further comprising: a sensor for measuring a voltage of the AC drive signal supplied to the ultrasonic handpiece; and a sensor for measuring a current of the AC drive signal supplied to the ultrasonic handpiece, wherein the processor is configured to determine the change in voltage to be developed across the primary winding based on the measured voltage and current of