Systems and methods providing controlled AC arc welding processes

What is claimed is: 1. A TIG welding power source comprising: a power conversion circuit configured to convert an input current to an output current; a main 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 a controller of the welding power source; and an auxiliary bridge circuit operatively connected to the main bridge circuit and configured to introduce a high impedance path between the power conversion circuit and the welding output circuit path at the command of the controller of the welding power source, wherein a welding output current of the welding power supply is an AC output current having a plurality of positive portions and negative portions and wherein said welding output current has a frequency of at least 1 KHz, and an average current output of at least 100 amps. 2. The power source of claim 1 , wherein said average output current is at least 200 amps. 3. The power source of claim 1 , wherein said average output current is at least 300 amps. 4. The power source of claim 1 , wherein said frequency is in the range of 1 to 2KHz, and said output current is in the range of 200 to 400 amps. 5. A TIG welding power source comprising: a power conversion circuit configured to convert an input current to an output current; a main 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 a controller of the welding power source; and an auxiliary bridge circuit operatively connected to the main bridge circuit and configured to introduce a high impedance path between the power conversion circuit and the welding output circuit path at the command of the controller of the welding power source, wherein a welding output current of the welding power supply is an AC output current having a plurality of positive portions and negative portions and wherein said welding output current has a frequency in the range of 500 to 999 Hz, and a waveform average current output of at least 100 amps, and wherein each of said positive and negative portions of said waveform have a peak-to-average current ratio in the range of 1.09 to 1.004. 6. The power source of claim 5 , wherein said peak-to-average current ratio is in the range of 1.05 to 1.01. 7. The power source of claim 5 , wherein each of said positive and negative portions of said waveform have a peak current time-to-polarity cycle time ratio in the range of 0.85 to 0.998, where for each of said respective negative and positive portions of the waveform the peak current time is the duration of time above 95% of the peak current level for said positive and negative portions, respectively, and said polarity cycle time is the duration of time of each of said positive and negative portions, respectively. 8. The power source of claim 7 , wherein said peak current time-to-polarity cycle time ratio is in the range of 0.9 to 0.997. 9. A TIG welding power source comprising: a power conversion circuit configured to convert an input current to an output current; a main 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 a controller of the welding power source; and an auxiliary bridge circuit operatively connected to the main bridge circuit and configured to introduce a high impedance path between the power conversion circuit and the welding output circuit path at the command of the controller of the welding power source, wherein a welding output current of the welding power supply is an AC output current having a plurality of positive portions and negative portions and wherein said welding output current has a frequency of at least 1 KHz, and a waveform average current output of at least 100 amps, and wherein each of said positive and negative portions of said waveform have a peak-to-average current ratio in the range of 1.2 to 1.04. 10. The power source of claim 9 , wherein said peak-to-average current ratio is in the range of 1.15 to 1.04. 11. The power source of claim 9 , wherein said frequency is in the range of 1 to 2 KHz. 12. The power source of claim 10 , wherein said frequency is in the range of 1 to 2 KHz. 13. The power source of claim 9 , wherein each of said positive and negative portions of said waveform have a peak current time-to-polarity cycle time ratio of at least 0.7, where for each of said respective negative and positive portions of the waveform the peak current time is the duration of time above 95% of the peak current level for said positive and negative portions, respectively, and said polarity cycle time is the duration of time of each of said positive and negative portions, respectively. 14. The power source of claim 13 , wherein the frequency is in the range of 1 to 2 KHz. 15. The power source of claim 13 , wherein the peak current time-to-polarity cycle time ratio is in the range of 0.7 and 0.9. 16. The power source of claim 15 , wherein the frequency is in the range of 1 to 2 KHz. 17. The power source of claim 13 , wherein the peak current time-to-polarity cycle time ratio is in the range of 0.75 and 0.88. 18. The power source of claim 17 , wherein the frequency is in the range of 1 to 2 KHz. 19. A TIG welding power source comprising: a power conversion circuit configured to convert an input current to an output current; a main 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 a controller of the welding power source; and an auxiliary bridge circuit operatively connected to the main bridge circuit and configured to introduce a high impedance path between the power conversion circuit and the welding output circuit path at the command of the controller of the welding power source, wherein a welding output current of the welding power supply is an AC output current having a plurality of positive portions and negative portions and wherein said welding output current has a frequency in the range of 500 to 999 Hz, and a waveform average current output of at least 100 amps, wherein each of said positive and negative portions of said waveform have a peak current time-to-polarity cycle time ratio in the range of 0.85 to 0.998, where for each of said respective negative and positive portions of the waveform the peak current time is the duration of time above 95% of the peak current level for said positive and negative portions, respectively, and said polarity cycle time is the duration of time of each of said positive and negative portions, respectively. 20. A TIG welding power source comprising: a power conversion circuit configured to convert an input current to an output current; a main 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 a controller of the welding pow