Method and apparatus for efficient switching in semi-resonant power converters

What is claimed is: 1. A voltage converter, comprising: a power stage that includes a high-side switch coupled to an input power source and a low-side switch coupled to the high-side switch at a switching node of the power stage; a passive circuit coupling the switching node to an output node of the voltage converter; a synchronous rectification (SR) switch stage configured to switchably couple the passive circuit to ground or another reference potential, wherein the SR switch stage comprises a plurality of SR switches connected in parallel to each other; and a control circuit configured to control which of the SR switches are on and which of the SR switches are off based upon an estimate of a current output of the voltage converter, wherein all of the SR switches are to be on if the estimated current output indicates a full-load condition and one or more of the SR switches are to be off if the estimated current output indicates a light-load condition so that fewer of the SR switches are on during the light-load condition than during the full-load condition. 2. The voltage converter of claim 1 , further comprising: a driver circuit that includes a plurality of drivers, the driver circuit inputting a common control signal that is provided to all of the drivers, each of the drivers providing a driver control signal that is coupled to a control terminal of an SR switch or control terminals of a group of SR switches for controlling an on or off state of the SR switch or the group of SR switches, and wherein an enable signal is input to the driver circuit to determine which drivers are enabled and which drivers are disabled, and wherein the control circuit is further configured to generate the common control signal and program the enable signal based upon the current output estimate, so as to enable each driver coupled to an SR switch or a group of SR switches that is to be turned on and to disable each driver coupled to an SR switch or a group of SR switches that is to be turned off. 3. The voltage converter of claim 2 , wherein the SR switches are of a same switch type and a same switch size, and wherein the enable signal indicates a number of the SR switches to activate. 4. The voltage converter of claim 2 , wherein conduction efficiencies of the SR switches differ substantively, and the enable signal indicates a particular one or particular ones of the SR switches to activate. 5. The voltage converter of claim 1 , further comprising: a driver circuit that includes a driver for each of the SR switches, each of the drivers coupling a control signal from the control circuit to a control terminal of an SR switch, and wherein the control circuit is further configured to activate the control signals for each of the SR switches that are to be turned on, and to deactivate the control signals for each of the SR switches that are to be turned off. 6. A multi-phase voltage converter operable to input power from an input power source and output power to an output node, the multi-phase voltage converter comprising: a plurality of power train circuits, each power train circuit comprising: a power stage that includes a high-side switch coupled to the input power source and a low-side switch that is coupled to the high-side switch at a switching node of the power stage; a passive circuit coupling the switching node to the output node of the multi-phase voltage converter; and a synchronous rectification (SR) switch stage configured to switchably couple the passive circuit to ground or another reference potential, wherein the SR switch stage comprises at least one SR switch, wherein the SR switch stage for at least one of the power train circuits includes a plurality of SR switches connected in parallel to each other, and a control circuit configured to control which of the SR switches are on and which of the SR switches are off based upon an estimate of a current output of the multi-phase voltage converter, wherein all of the SR switches are to be on if the estimated current output indicates a full-load condition and one or more of the SR switches are to be off if the estimated current output indicates a light-load condition so that fewer of the SR switches are on during the light-load condition than during the full-load condition. 7. The multi-phase voltage converter of claim 6 , wherein each of the power train circuits further comprises: a driver circuit that includes a plurality of drivers, the driver circuit inputting a common control signal that is provided to each of the drivers, each of the drivers providing a driver control signal coupled to a control terminal of an SR switch or control terminals of a group of SR switches for controlling an on or off state of the SR switch or the group of SR switches, and wherein an enable signal is input to the driver circuit to determine which drivers are enabled and which drivers are disabled, and wherein the control circuit is further configured to generate the common control signal and to program the enable signal based upon the current output estimate, so as to enable each driver coupled to an SR switch or a group of SR switches that is to be turned on and to disable each driver coupled to an SR switch or a group of SR switches that is to be turned off. 8. The multi-phase voltage converter of claim 7 , wherein the SR switches are of a same switch type and a same switch size, and wherein the enable signal for each power train circuit indicates a number of the SR switches to activate within that power train circuit. 9. The multi-phase voltage converter of claim 7 , wherein conduction efficiencies of the SR switches differ substantively, and the enable signal for each power train circuit indicates a particular one or particular ones of the SR switches to activate within that power train circuit. 10. The multi-phase voltage converter of claim 6 , wherein each of the power train circuits further comprises: a driver circuit that includes a driver for each of the SR switches of the power train circuit, each of the drivers coupling a distinct control signal from the control circuit to a control terminal of an SR switch, and wherein the control circuit is further configured to activate the control signals for each of the SR switches that are to be turned on, and to deactivate the control signals for each of the SR switches that are to be turned off. 11. The multi-phase voltage converter of claim 6 , wherein each of the power train circuits includes a same number of SR switches, and the control circuit turns on the same number of switches in each of the power train circuits. 12. The multi-phase voltage converter of claim 6 , wherein the control circuit is further configured to turn on all of the SR switches for all of the power train circuits responsive to determining that the estimated current output is above a first predetermined threshold and, otherwise, to turn on one or more SR switches within a first of the power train circuits and to turn off all of the SR switches within all except the first of the power train circuits. 13. The multi-phase voltage converter of claim 12 , wherein the control circuit, responsive to a determination that the estimated current output is below a second predetermined level, turns on a single SR switch within the first power rain circuit and turns off all remaining SR switches within the first power train circuit. 14. The multi-phase voltage converter of claim 6 , wherein the SR switch stage corresponding to a first of the plurality of power train circuits has a first number of SR switches that differs from a second number of SR switches within the SR switch stage correspo