Power converter with extended hold-up time

What is claimed is: 1. An AC-DC converter system comprising: an input configured to receive input AC power from an AC source; an output configured to provide output DC power having an output DC voltage to a load; a rectifier coupled to the input; a capacitor coupled to the rectifier; a DC bus coupled to the capacitor; a plurality of first switches coupled to the DC bus; a plurality of second switches coupled between the rectifier and the plurality of first switches; a transformer having a primary winding and a secondary winding, the primary winding coupled to the plurality of first switches, the plurality of second switches, and the rectifier, and the secondary winding coupled to the output; and a controller configured to monitor the input AC power and, in response to a determination that the input AC power is acceptable, to: operate the plurality of second switches and the plurality of first switches such that the output DC voltage is maintained at a desired output DC voltage level; and operate the plurality of first switches such that a DC bus voltage on the DC bus is maintained at a desired DC bus voltage level, wherein in operating the plurality of second switches and the plurality of first switches such that the output DC voltage is maintained at the desired output DC voltage level, the controller is further configured to operate the plurality of second switches and the plurality of first switches in a complementary manner. 2. The AC-DC converter system of claim 1 , wherein in operating the plurality of first switches such that a DC bus voltage on the DC bus is maintained at a desired DC bus voltage level, the controller is further configured to reduce a duty cycle of a control signal provided to the plurality of first switches in response to the DC bus voltage approaching the desired DC bus voltage level. 3. The AC-DC converter system of claim 1 , further comprising a first inductor, wherein the primary winding of the transformer includes a center tap and wherein the center tap is coupled to the rectifier via the first inductor. 4. The AC-DC converter system of claim 3 , further comprising a second inductor, wherein the primary winding is coupled to the plurality of first switches via the second inductor. 5. The AC-DC converter system of claim 4 , further comprising a third inductor, wherein the primary winding is coupled to the plurality of second switches via the third inductor. 6. The AC-DC converter system of claim 1 , wherein in response to a determination that the input power is unacceptable, the controller is further configured to operate, in a hold-up mode of operation, the plurality of second switches and the plurality of first switches to draw energy from the capacitor such that the output DC voltage is maintained at the desired output DC voltage level for a hold-up period of time. 7. The AC-DC converter system of claim 6 , wherein the hold-up period of time is at least 10 ms. 8. The AC-DC converter system of claim 6 , wherein in operating the plurality of second switches and the plurality of first switches in the hold-up mode of operation, the controller is further configured to operate the plurality of second switches and the plurality of first switches in a full-bridge phase shift mode of operation. 9. The AC-DC converter system of claim 6 , wherein in operating the plurality of second switches and the plurality of first switches in the hold-up mode of operation, the controller is further configured to operate the plurality of second switches and the plurality of first switches in a full-bridge Pulse Width Modulation (PWM) mode of operation. 10. A method for operating an AC-DC converter system comprising an input, an output, a rectifier coupled to the input, a capacitor coupled to the rectifier, a DC bus coupled to the capacitor, a plurality of first switches coupled to the DC bus, a plurality of second switches coupled between the rectifier and the plurality of first switches, and a transformer having a primary winding and a secondary winding, the primary winding coupled to the plurality of first switches, the plurality of second switches, and the rectifier, and the secondary winding coupled to the output, wherein the method comprises acts of: receiving input AC power at the input from an AC source; determining whether the input AC power is acceptable; in response to a determination that the AC power is acceptable, operating the plurality of second switches and the plurality of first switches such that an output DC voltage level is maintained at the output; and in response to a determination that the AC power is acceptable, operating the plurality of first switches such that a DC bus voltage level is maintained on the DC bus, wherein the act of operating the plurality of second switches and the plurality of first switches such that the output DC voltage level is maintained at the output includes operating the plurality of second switches and the plurality of first switches in a complementary manner. 11. The method of claim 10 , wherein the act of operating the plurality of second switches and the plurality of first switches such that the output DC voltage level is maintained at the output further includes acts of: monitoring the output DC voltage level; comparing the output DC voltage level to a reference output voltage level; and operating, based on the act of comparing the output DC voltage level to the reference output voltage level, the plurality of second switches and the plurality of first switches to drive the output DC voltage level towards the reference output voltage level. 12. The method of claim 11 , wherein the act of operating the plurality of first switches such that the DC bus voltage level is maintained on the DC bus further includes acts of: monitoring the DC bus voltage level; comparing the DC bus voltage level to a reference bus voltage level; and operating, based on the act of comparing the DC bus voltage level to the reference bus voltage level, the plurality of first switches to drive the DC bus voltage level towards the reference bus voltage level. 13. The method of claim 12 , wherein the act of operating the plurality of first switches to drive the DC bus voltage level towards the reference bus voltage level includes reducing a duty cycle of a control signal provided to the plurality of first switches in response to the DC bus voltage approaching the desired DC bus voltage level. 14. The method of claim 13 , wherein reducing the duty cycle of the control signal includes reducing the duty cycle of the control signal by a factor of K, and wherein the method further comprises an act of calculating, with a Proportional-Integral (PI) controller based on the act of comparing the DC bus voltage level to the reference bus voltage level, the factor of K. 15. The method of claim 10 , wherein the method further comprises: in response to a determination that the AC power is unacceptable, operating, in a hold-up mode of operation, the plurality of second switches and the plurality of first switches to draw energy from the capacitor such that the output DC voltage level is maintained at the output for a hold-up period of time. 16. The AC-DC converter system of claim 15 , wherein operating the plurality of second switches and the plurality of first switches in the hold-up mode of operation includes operating the plurality of second switches and the plurality of first switches in one of a full-bridge phase shift mode of operation and a full-bridge PWM mode of operation. 17. An AC-DC converter system comprising: an input config