Tandem hot-wire systems

What is claimed is: 1. A welding system, said system comprising: a torch; a first wire feeder that feeds a first wire to said torch; a welding power supply that outputs a welding current waveform to said first wire via said torch, said welding current waveform including a first current segment that is output when said first wire is in contact with a workpiece to melt and transfer a portion of said first wire, and a second current segment that is output during an arcing period between said first wire and said workpiece, an arc creating a molten puddle on said workpiece; a second wire feeder that feeds a second wire to said molten puddle via a contact tube such that said second wire enters said molten puddle; a hot-wire power supply that outputs a heating current waveform that includes at least one of first heating current pulses, which influence said transfer of said portion of said first wire based on magnetic fields created by said welding current waveform and said heating current waveform, and second heating current pulses, which influence a position of said arc relative to said molten puddle based on said magnetic fields created by said welding current waveform and said heating current waveform, said hot-wire power supply providing said heating current waveform to said second wire via said contact tube; and a controller operably connected to said welding power supply and said hot-wire power supply and configured to perform at least one of a first synchronization by controlling a first phase angle between said first heating current pulses and said first current segment and a second synchronization by controlling a second phase angle between said second heating current pulses and said second current segment. 2. The system of claim 1 , wherein said heating current waveform includes both said first heating current pulses and said second heating current pulses, and wherein said controller performs both said first synchronization and said second synchronization. 3. The system of claim 1 , wherein said influencing said position of said arc comprises deflecting said arc toward said second wire by setting said magnetic fields to flow in a same direction, and deflecting said arc away from said second wire by setting said magnetic fields to flow in opposite directions. 4. The system of claim 1 , wherein said heating current waveform includes said second heating current pulses, and wherein said second heating current pulses and said second current segment have a same polarity. 5. The system of claim 1 , wherein said heating current waveform includes said second heating current pulses, and wherein said second heating current pulses and said second current segment have opposite polarities. 6. The system of claim 1 , wherein said heating current waveform includes said first heating current pulses, and wherein said controller performs said first synchronizing, which includes synchronizing said first heating current pulses to start at a desired phase angle from when said first wire shorts to said molten puddle. 7. The system of claim 1 , wherein said heating current waveform includes said second heating current pulses, and wherein said controller performs said second synchronizing, which includes synchronizing said second heating current pulses to start at a desired phase angle from a start of said arcing period. 8. The system of claim 6 , wherein said controller uses one of an output voltage and an output current of said welding power supply to determine when said first wire shorts to said molten puddle. 9. The system of claim 7 , wherein said controller uses one of an output voltage and an output current of said welding power supply to determine when said first wire is in said arcing period. 10. The system of claim 1 , wherein said welding current waveform is a waveform corresponding to a short arc transfer process, a surface tension transfer process, or a shorted retract welding process. 11. A method of welding, said method comprising: feeding a first wire to a torch; providing a welding current waveform to said first wire via said torch, said welding current waveform including a first current segment that is provided when said first wire is in contact with a workpiece to melt and transfer a portion of said first wire, and a second current segment that is provided during an arcing period with an arc between said first wire and said workpiece, said arc creating a molten puddle on said workpiece; feeding a second wire to said molten puddle via a contact tube such that said second wire enters said molten puddle; providing a heating current waveform that includes at least one of first heating current pulses, which influence said transfer of said portion of said first wire based on magnetic fields created by said welding current waveform and said heating current waveform, and second heating current pulses, which influence a position of said arc relative to said molten puddle based on said magnetic fields created by said welding current and said heating current; providing said heating current waveform to said second wire via said contact tube; and performing at least one of a first synchronization controlling a first phase angle between said first heating current pulses and said first current segment and a second synchronization by controlling a second phase angle between said second heating current pulses and said second current segment. 12. The method of claim 11 , wherein said heating current waveform includes both said first heating current pulses and said second heating current pulses, and wherein said method comprises performing both said first synchronization and said second synchronization. 13. The method of claim 11 , wherein said influencing said position of said arc comprises deflecting said arc toward said second wire by setting said magnetic fields to flow in a same direction, and deflecting said arc away from said second wire by setting said magnetic fields to flow in opposite directions. 14. The method of claim 11 , wherein said heating current waveform includes said second heating current pulses, and wherein said second heating current pulses and said second current segment have a same polarity. 15. The method of claim 11 , wherein said heating current waveform includes said second heating current pulses, and wherein said second heating current pulses and said second current segment have opposite polarities. 16. The method of claim 11 , wherein said heating current waveform includes said first heating current pulses, and wherein said method further comprises performing said first synchronizing, which includes synchronizing said first heating current pulses to start at a desired phase angle from when said first wire shorts to said molten puddle. 17. The method of claim 16 , further comprising: determining when said first wire shorts to said molten puddle based on one of a voltage and a current in said first wire. 18. The method of claim 11 , wherein said heating current waveform includes said second heating current pulses, and wherein said method further comprises performing said second synchronizing, which includes synchronizing said second heating current pulses to start at a desired phase angle from a start of said arcing period. 19. The method of claim 18 , further comprising: determining when said first wire is in said arcing period based on one of a voltage and a current in said first wire. 20. The method of claim 11 , wherein said welding current waveform is a waveform correspon