Auxiliary commutated silicon-controlled rectifier circuit methods and systems

What is claimed is: 1. A device comprising: an input terminal; an output terminal; a first silicon-controlled rectifier (SCR); a second silicon-controlled rectifier (SCR) connected in anti-parallel with the first SCR; a first commutation module comprising a first voltage source, a first diode, and a first self-commutating semiconductor switch, wherein: the first voltage source, the first diode, and the first self-commutating semiconductor switch of the first commutation module are connected in series, the first SCR is connected in parallel to the first commutation module, and the first commutation module is configured to apply a first reverse bias voltage to the first SCR to turn off the first SCR, and; a second commutation module comprising a second voltage source, a second diode, and a second self-commutating semiconductor switch, wherein: the second voltage source, the second diode, and the second self-commutating semiconductor switch of the second commutation module are connected in series, the first SCR, the second SCR, the first commutation module, and the second commutation module are connected in parallel, and the second commutation module is configured to apply a second reverse bias voltage to the second SCR to turn off the second SCR, wherein the first voltage source is connected to the input terminal and the first self-commutating semiconductor switch is connected to the output terminal. 2. The device of claim 1 , wherein the first self-commutating semiconductor switch comprises a first self-commutating transistor device and a third diode connected in anti-parallel. 3. The device of claim 1 , wherein: the input terminal is configured to receive a first operating signal; and the output terminal is in electrical communication with the input terminal and through which the first operating signal is provided to a load. 4. The device of claim 1 , further comprising: a regulator module configured to generate a correction signal during at least a portion of a voltage sag or voltage swell; and an alternating current (AC) static switch in electrical communication with the input terminal and the output terminal, wherein: the AC static switch comprises the first SCR, the second SCR, the first commutation module, and the second commutation module, the regulator module is connected to the output terminal, the AC static switch is in a closed position during a normal operating condition such that the regulator module is bypassed, and the AC static switch is in an open position during at least a portion of the voltage sag or voltage swell such that the regulator module is not bypassed. 5. The device of claim 4 , further comprising a device controller configured to detect the voltage sag or voltage swell. 6. The device of claim 1 , wherein: the first self-commutating semiconductor switch and the second self-commutating semiconductor switch are a self-commutating semiconductor switch pair; and the first diode and the second diode are a diode pair. 7. The device of claim 1 , wherein the first self-commutating semiconductor switch comprises a first self-commutating transistor device and a third diode connected in anti-parallel, and the second self-commutating semiconductor switch comprises a second self-commutating transistor device and a fourth diode connected in anti-parallel. 8. The device of claim 1 , further comprising a snubber configured to dissipate energy when the first SCR or the second SCR are turned off. 9. The device of claim 8 , wherein the snubber is connected in parallel with the first self-commutating semiconductor, the second self-commutating semiconductor switch, the first SCR, or the second SCR. 10. The device of claim 8 , wherein the snubber comprises a resistance and capacitance connected in series. 11. The device of claim 1 , further comprising a voltage clamp configured to dissipate energy when the first SCR or the second SCR are turned off, wherein the voltage clamp references a system common or an alternating current (AC) source common. 12. The device of claim 11 , further comprising a dynamic brake configured to dissipate energy from the voltage clamp. 13. The device of claim 1 , wherein the second self-commutating semiconductor switch is connected to the input terminal and the second voltage source is connected to the output terminal. 14. The device of claim 1 , wherein an anode of the first diode is directly connected to the first voltage source and a cathode of the first diode is directly connected to the first self-commutating semiconductor switch, and wherein an anode of the second diode is directly connected to the second voltage source and a cathode of the second diode is directly connected to the second self-commutating semiconductor switch. 15. The device of claim 1 wherein an anode of the first SCR and an anode of the first diode face the input terminal, and a cathode of the first SCR and a cathode of the first diode face the output terminal, and wherein an anode of the second SCR and an anode of the second diode face the output terminal, and a cathode of the second SCR and a cathode of the second diode face the input terminal. 16. A method comprising: connecting a first silicon-controlled rectifier (SCR) and a first commutation module in parallel, wherein the first commutation module comprises a first voltage source, a first diode, and a first self-commutating semiconductor switch connected in series; connecting a second silicon-controlled rectifier (SCR) in anti-parallel with the first SCR, wherein the first SCR, the second SCR, the first commutation module, and a second commutation module are connected in parallel, and wherein the second commutation module comprises a second voltage source, a second diode, and a second self-commutating semiconductor switch connected in series; connecting a load to an operating signal; passing the operating signal through the SCR to the load; applying, by the first commutation module, a first reverse bias voltage to the first SCR to turn off the first SCR; and applying, by the second commutation module, a second reverse bias voltage to the second SCR to turn off the second SCR, wherein the first voltage source is connected to an input terminal that is configured to receive the operating signal, and wherein the first self-commutating semiconductor switch is connected to the load. 17. The method of claim 16 , further comprising: connecting an alternating current (AC) static switch and the first commutation module in parallel, wherein the AC static switch comprises the first SCR and the second SCR; connecting the load to the operating signal through the AC static switch during a normal operating condition, wherein the AC static switch is in a closed position during the normal operating condition; detecting, by a controller, a voltage sag or voltage swell; and applying the reverse bias voltage to the first SCR or the second SCR of the AC static switch, wherein the AC static switch is in an open position during at least a portion of the voltage sag or voltage swell, and further wherein the reverse bias voltage turns off the first SCR or the second SCR. 18. The method of claim 17 , further comprising: connecting a regulator module to the output terminal, wherein during the normal operating condition the regulator module is bypassed; generating, by the regulator module, a correction signal during at least a portion of the voltage sag or voltage swell; switching the AC static switch to the open position by applying the reverse bias voltage to the AC