TIG welding system

What is claimed is: 1. A TIG welding system comprising: a power source having a controller in communication therewith, the controller having a memory storing at least one waveform, the at least one waveform including an arc initiation stage and a sequencing stage; a welding torch including an electrode electrically connected to the controller, the electrode having a length and a diameter; and an amperage input in communication with the controller and adapted to receive a user-selected welding amperage; wherein the controller is programmed to select one of the at least one waveform based on the user-selected welding amperage and apply power from the power source to the electrode according to the selected at least one waveform; wherein the at least one waveform includes a transition from the arc initiation stage to the sequencing stage, the arc initiation stage including at least one pulse, wherein the arc initiation stage includes an arc initiation waveform that is selected by the controller from a plurality of arc initiation waveforms, the arc initiation waveform in the arc initiation stage corresponding to the user-selected welding amperage. 2. The TIG welding system of claim 1 , wherein the at least one waveform includes a start current greater than 2 amps and less than the welding amperage to provide early delivery of power to a weld pool, and wherein during the arc initiation stage, the at least one waveform includes a transition from an arc initiation current to the start current to start the sequencing stage, wherein during the sequencing stage, the at least one waveform transitions from the start current to the welding amperage. 3. The TIG welding system of claim 2 , wherein the arc initiation stage includes plural pulses, and wherein the transition includes plural pulses, each having a pulse height, wherein the pulse height of each is progressively reduced until reaching the start current. 4. The TIG welding system of claim 1 , wherein the arc initiation waveform includes a pulse height parameter, and a pulse duration parameter. 5. The TIG welding system of claim 4 , wherein the arc initiation waveform further includes a positive to negative pulse ratio. 6. The TIG welding system of claim 5 , wherein the positive to negative pulse ratio is less than 1. 7. The TIG welding system of claim 1 further comprising a sensor adapted to detect the diameter of the electrode, the sensor being in communication with the controller; wherein the controller determines whether the electrode diameter and the user-selected amperage are compatible before applying power to the electrode. 8. The TIG welding system of claim 1 , wherein the amperage input includes an arc initiation amperage. 9. The TIG welding system of claim 1 , wherein the at least one waveform further includes a sequencing stage, the sequencing stage having a start current, wherein the at least one waveform transitions from the arc initiation stage to the sequencing stage by tapering one or more pulses following the at least one pulse of the arc initiation stage toward the start current, wherein the start current is not equal to the welding amperage. 10. The TIG welding system of claim 9 further comprising a start current input in communication with the controller, wherein the start current input establishes the start current for the sequencing stage of the at least one waveform. 11. The TIG welding system of claim 8 , wherein during the sequencing stage, the controller transfers control of the arc current or voltage to a user operated controller. 12. The TIG welding system of claim 11 wherein within the sequencing stage, the at least one waveform further includes a tail down portion, where control of the arc current or voltage is transferred from the user-operated controller to the controller, and the controller is configured to prevent user control of the arc current or voltage during the tail down portion, and wherein during the tail down portion, the at least one waveform reduces the current to a selected low value. 13. The TIG welding system of claim 12 , wherein the selected low value is less than two amps. 14. A method of controlling a TIG welder comprising: receiving an amperage input; selecting, by a controller, a waveform from a memory based on the amperage input, the waveform including parameters extrapolated according to the amperage input, the waveform including an arc initiation stage and a sequencing stage, wherein the arc initiation stage includes an arc initiation waveform that is selected by the controller from a plurality of arc initiation waveforms, the arc initiation waveform in the arc initiation stage corresponding to the amperage input; and energizing an electrode according to the waveform, wherein the waveform includes a transition from the arc initiation stage to the sequencing stage, the arc initiation stage including at least one pulse. 15. The method of claim 14 , wherein the parameters include an amplitude, a duration, and a restrike number of the at least one pulse. 16. The method of claim 15 , wherein the waveform includes a start current greater than 2 amps and less than the amperage input, wherein the parameters further include a pulse taper profile to the start current. 17. The method of claim 15 , wherein the parameters further include a tail out current and post flow. 18. The method of claim 14 further comprising receiving a start current input and, wherein the arc initiation waveform transitions from the arc initiation stage current to the start current to begin the sequencing stage. 19. The method of claim 18 , wherein the transition includes tapering the amplitude of the at least one pulse downward and upward toward the start current. 20. The method of claim 19 wherein during the sequencing stage, the at least one waveform ramps from the start current to a welding current corresponding to the amperage input, and wherein upon attaining the welding current, the controller permits user control of the energy to the electrode.