Switched mode converter with low-voltage turn-around mode

What is claimed is: 1. A switching power stage for producing an output voltage to a load, comprising: a power converter comprising a power inductor and a plurality of switches arranged to sequentially operate in a plurality of switch configurations; a controller configured to sequentially apply the plurality of switch configurations to selectively activate or deactivate each of the plurality of switches in order to operate the power converter in a plurality of modes including at least a turn-around mode and a boost mode, wherein: in the turn-around mode, the controller operates the converter as a differential output converter to switch a polarity of the output voltage, such that: during a charging phase of the power converter, the power inductor is coupled between (i) one of a first terminal of a power source and a second terminal of the power source and (ii) one of a first terminal of an output load and a second terminal of the output load; during a transfer phase of the power converter, at least one of the plurality of switches is activated in order to couple the power inductor between the second terminal of the power source and one of the first terminal of the output load and the second terminal of the output load; and the output voltage comprises a differential voltage between the first terminal and the second terminal; and in the boost mode, the controller operates the converter as a boost converter in order to boost one of the first terminal and the second terminal to a voltage greater than a supply voltage to the switching power stage; and a capacitor coupled to one of the first terminal and the second terminal, wherein the capacitor is coupled to the power inductor via at least one switch of the plurality of switches. 2. The switching power stage of claim 1 , wherein the controller is further configured to regulate a common mode voltage of the first terminal of the output load and the second terminal of the output load at a predetermined voltage. 3. The switching power stage of claim 2 , wherein the predetermined voltage is approximately equal to one-half of a source voltage provided by an input source. 4. The switching power stage of claim 2 , wherein: the first terminal of the power source has a larger voltage potential than the second terminal of the power source; and the controller is configured to regulate the common mode voltage during the charging phase by: coupling the power inductor between the first terminal of the power source and one of the first terminal of the output load and the second terminal of the output load to increase the common mode voltage; and coupling the power inductor between the second terminal of the power source and one of the first terminal of the output load and the second terminal of the output load to decrease the common mode voltage. 5. The switching power stage of claim 1 , wherein: the first terminal of the power source has a larger voltage potential than the second terminal of the power source; and the controller is configured to decrease the output voltage during the transfer phase by coupling the power inductor between the second terminal of the power source and the second terminal of the output load. 6. The switching power stage of claim 1 , wherein: the first terminal of the power source has a larger voltage potential than the second terminal of the power source; and the controller is configured to increase the output voltage during the transfer phase by coupling the power inductor between the second terminal of the power source and the first terminal of the output load. 7. The switching power stage of claim 1 , wherein the load is an acoustic transducer. 8. The switching power stage of claim 1 , wherein the controller controls switching of the plurality of switches to produce the output voltage as a function of an input signal. 9. The switching power stage of claim 8 , wherein the input signal is an audio signal. 10. A method for producing an output voltage to a load, comprising: in a power converter comprising a power inductor, a plurality of switches arranged to sequentially operate in a plurality of switch configurations, sequentially applying a plurality of switch configurations to selectively activate or deactivate each of the plurality of switches in order to operate the power converter in a plurality of modes including at least a turn-around mode and a boost mode, wherein: in the turn-around mode, the controller operates the converter as a differential output converter to switch a polarity of the output voltage, such that: during a charging phase of the power converter, the power inductor is coupled between (i) one of a first terminal of a power source and a second terminal of the power source and (ii) one of a first terminal of an output load and a second terminal of the output load; during a transfer phase of the power converter, at least one of the plurality of switches is activated in order to couple the power inductor between the second terminal of the power source and one of the first terminal of the output load and the second terminal of the output load; and the output voltage comprises a differential voltage between the first terminal and the second terminal; and in the boost mode, the controller operates the converter as a boost converter in order to boost one of the first terminal and the second terminal to a voltage greater than a supply voltage to the switching power stage; and wherein a capacitor is coupled to one of the first terminal and the second terminal, wherein the capacitor is coupled to the power inductor via at least one switch of the plurality of switches. 11. The method of claim 10 , further comprising regulating a common mode voltage of the first terminal of the output load and the second terminal of the output load at a predetermined voltage. 12. The method of claim 11 , wherein the predetermined voltage is approximately equal to one-half of a source voltage provided by an input source. 13. The method of claim 11 , wherein: the first terminal of the power source has a larger voltage potential than the second terminal of the power source; and the method further comprises regulating the common mode voltage during the charging phase by: coupling the power inductor between the first terminal of the power source and one of the first terminal of the output load and the second terminal of the output load to increase the common mode voltage; and coupling the power inductor between the second terminal of the power source and one of the first terminal of the output load and the second terminal of the output load to decrease the common mode voltage. 14. The method of claim 10 , wherein: the first terminal of the power source has a larger voltage potential than the second terminal of the power source; and the method further comprises decreasing the output voltage during the transfer phase by coupling the power inductor between the second terminal of the power source and the second terminal of the output load. 15. The method of claim 10 , wherein: the first terminal of the power source has a larger voltage potential than the second terminal of the power source; and the method further comprises increasing the output voltage during the transfer phase by coupling the power inductor between the second terminal of the power source and the first terminal of the output load. 16. The method of claim 10 , wherein the load is an acoustic transducer. 17. The method of claim 10 , further comprising controlling switching of the plurality of switches to produce the output v