Systems and methods providing low current regulation for AC arc welding processes

What is claimed is: 1. A welding power source comprising: a power conversion circuit configured to convert an input current to an output current; a controller; a bridge circuit operatively connected to the power conversion circuit and configured to switch a direction of the output current through a welding output circuit path operatively connected to a welding output of the welding power source at the command of the controller; an arc regulation circuit operatively connected to the bridge circuit and configured to induce a voltage between an electrode and a workpiece of the welding output circuit path sufficient for arc re-ignition during polarity transition of the output current, and further configured to induce an overshoot current to facilitate arc re-ignition during at least a negative to positive polarity transition of the output current; wherein the arc regulation circuit comprises: an inductor configured to store energy; and a constant current source configured to supply regulated constant current to the inductor; and wherein an output of the arc regulation circuit is connected to the bridge circuit. 2. The welding power source of claim 1 , wherein the arc regulation circuit includes a superposition capacitor configured to provide the overshoot current. 3. The welding power source of claim 2 , wherein the arc regulation circuit includes an independent discharge control switch configured to selectively discharge the superposition capacitor during the negative to positive polarity transition of the output current. 4. The welding power source of claim 3 , wherein an inductance value of the at least one inductor is between about 10 to 100 milli-henries. 5. The welding power source of claim 1 , wherein the constant current source is configured to provide an adjustable current of between 2 amps and 10 amps. 6. The welding power source of claim 1 , wherein the power conversion circuit, the bridge circuit, and the arc regulation circuit are configured to provide any of a DC positive welding operation, a DC negative welding operation, and an AC welding operation at the command of the controller of the welding power source. 7. The welding power source of claim 1 , wherein the power conversion circuit is transformer based with a half bridge output topology. 8. The welding power source of claim 1 , wherein the power conversion circuit includes a DC output topology. 9. The welding power source of claim 1 , wherein the power conversion circuit is a chopper-based circuit. 10. The welding power source of claim 1 , wherein the bridge circuit includes at least two switching transistors. 11. A welding power source comprising: means for converting an input current to an output current; means for switching a direction of the output current through a welding output circuit path operatively connected to a welding output of the welding power source to provide at least an AC welding operation; means for inducing a voltage between a welding electrode and a welding workpiece of the welding output circuit path during a polarity transition of the output current to automatically re-establish an arc between the welding electrode and the workpiece in an opposite polarity, wherein an output of the means for inducing a voltage is connected to the means for switching a direction of the output current; and means for inducing an overshoot current to facilitate arc re-ignition during at least a negative to positive polarity transition of the output current, wherein the means for inducing an overshoot current comprises an inductor and a constant current source configured to supply regulated constant current to the inductor. 12. A method comprising: converting an input current to an output current in a welding power source; switching, using a bridge circuit, a direction of the output current through a welding output circuit path operatively connected to a welding output of the welding power source from a first direction to a second direction at the command of a controller of the welding power source; inducing, using an arc regulation circuit, a voltage level between a welding electrode and a workpiece of the welding output circuit path sufficient to automatically re-ignite an arc between the electrode and the workpiece in the second direction as part of switching to the second direction; and inducing, using the arc regulation circuit, an overshoot current to facilitate arc re-ignition during at least a negative to positive polarity transition of the output current, wherein inducing the overshoot current comprises supplying a regulated constant current from a constant current source of the arc regulation circuit to an inductor of the arc regulation circuit, and wherein an output of the arc regulation circuit is connected to the bridge circuit. 13. The method of claim 12 , further comprising: switching a direction of the output current through the welding output circuit path from the second direction to the first direction at the command of the controller of the welding power source; and inducing a voltage level between the welding electrode and the workpiece of the welding output circuit path sufficient to automatically re-ignite an arc between the electrode and the workpiece in the first direction as part of switching to the first direction. 14. The method of claim 12 , wherein the step of inducing an overshoot current is achieved by the arc regulation circuit having at least on superposition capacitor. 15. A welding power source comprising: a bridge circuit configured to provide an AC welding output current; and an arc regulation circuit operatively connected to the bridge circuit and configured to induce a voltage at a welding output of the welding power source being of sufficient magnitude to automatically re-ignite an arc in an output circuit path connected to the welding output upon reversal of a polarity of the welding output current through the output circuit path, and further configured to induce an overshoot current to facilitate arc re-ignition during at least a negative to positive polarity transition of the output current; the arc regulation circuit comprising: an inductor configured to store energy; and a constant current source configured to supply regulated constant current to the inductor; and wherein an output of the arc regulation circuit is connected to the bridge circuit. 16. A welding power source comprising: a current switching circuit comprising: at least one inductor, at least one constant current source connected in series with the at least one inductor and configured to supply regulated constant current to the at least one inductor, and at least one superposition capacitor, wherein the at least one inductor, the at least one constant current source, and the at least one superposition capacitor are configured to induce a voltage across a load connected to a welding output of the welding power source sufficient to re-ignite a welding arc across the load upon reversal of a polarity of a welding output current through the load; and wherein the at least one superposition capacitor is connected in parallel to the at least one inductor and the at least one constant current source. 17. The welding power source of claim 16 , wherein the current switching circuit is configured as one of a half bridge circuit or a full bridge circuit. 18. The welding power source of claim 1 , wherein the constant current source comprises at least one of: a chopper buck regulator; or a voltage source and a resistor. 19. The welding powe