System and method for controlling wire feed speed

The invention claimed is: 1. A method of controlling a welding system comprising: receiving an input via an operator interface relating to an operator preference; providing a welding wire to a welding torch at a first wire feed speed; providing a pulsed power output to the welding wire via a contact point of the welding torch; determining, utilizing a sensing system, a contact-point-to-work-distance (CPWD) between the contact point and a workpiece, wherein determining the CPWD comprises determining an arc length based at least in part on the pulsed power output, determining a resistance of a powered portion of the welding wire based at least in part on the pulsed power output, determining an electrode extension based at least in part on a functional relationship between the resistance and the electrode extension, and determining the CPWD based at least in part on the arc length and the electrode extension; and changing, utilizing a controller, a wire feed speed of the welding wire to a second wire feed speed during an operator-controlled weld based at least in part on the determined CPWD and the input of the operator preference received via the operator interface. 2. The method of claim 1 , wherein the arc length comprises a distance between a powered end of the welding wire and the workpiece—and the powered portion comprises a portion of the welding wire between the contact point and the powered end of the welding wire. 3. The method of claim 1 , wherein the first wire feed speed is functionally related to the second wire feed speed by a gain factor, and the gain factor is based on the input, a look-up table, a functional relationship, or a wire feed speed range of the welding system, or any combination thereof. 4. The method of claim 3 , comprising setting the gain factor, utilizing the operator interface, prior to initiating formation of the weld based at least in part on the operator preference, wherein the operator interface is disposed on the welding torch of the welding system, on a wire feeder of the welding system, or on a power source of the welding system. 5. The method of claim 1 , wherein the second wire feed speed is greater than the first wire feed speed when the determined CPWD decreases, and the second wire feed speed is less than the first wire feed speed when the determined CPWD increases. 6. The method of claim 1 , comprising controlling penetration of a weld into the workpiece based at least in part on the determined CPWD. 7. The method of claim 1 , wherein changing the wire feed speed of the welding wire to the second wire feed speed occurs during formation of a weld without manual adjustment of controls of the welding torch of the welding system, manual adjustment of a wire feeder of the welding system, or manual adjustment of a power source of the welding system. 8. The method of claim 1 , wherein the welding system comprises an automated welding system. 9. A method of controlling a welding system comprising: providing a welding wire to a welding torch at a first wire feed speed; providing a pulsed power output to the welding wire via a contact point of the welding torch; determining, utilizing a sensing system, a contact-point-to-work-distance (CPWD) between the contact point and a workpiece, wherein determining the CPWD comprises: determining an arc length based at least in part on the pulsed power output, wherein the arc length comprises a distance between an end of the welding wire and the workpiece; determining a resistance of a powered portion of the welding wire based at least in part on the pulsed power output, wherein the powered portion comprises a portion of the welding wire between the contact point and the end of the welding wire; determining an electrode extension based at least in part on a functional relationship between the resistance and the electrode extension; and determining the CPWD based at least in part on a sum of the arc length and the electrode extension; and changing, utilizing a controller, a wire feed speed of the welding wire from the first wire feed speed by a gain factor to a second wire feed speed during an operator-controlled weld based at least in part on the determined CPWD, wherein the gain factor is set based at least in part on an operator preference received via an operator interface of the welding system. 10. The method of claim 9 , wherein the second wire feed speed is greater than the first wire feed speed when the determined CPWD decreases, and the second wire feed speed is less than the first wire feed speed when the determined CPWD increases. 11. The method of claim 9 , comprising controlling the CPWD based at least in part on a gap condition of the workpiece, a welding position of the welding torch, or any combination thereof. 12. The method of claim 9 , comprising setting the gain factor prior to initiating formation of a weld based at least in part on the operator preference, wherein the gain factor is set via the operator interface of a power source or a wire feeder of the welding system. 13. The method of claim 9 , wherein changing the wire feed speed of the welding wire occurs during formation of a weld without manual adjustment of a user control disposed on a welding power source of the welding system, on a wire feeder of the welding system, or on the welding torch of the welding system. 14. A welding system comprising: an operator interface configured to receive an input relating to an operator preference; a wire feeder coupled to a torch and configured to provide a welding wire to the torch, wherein the torch comprises a contact tip with a contact point; a sensing system configured to determine a contact-point-to-work-distance (CPWD) between the contact point of the torch and a workpiece, wherein the sensing system is configured to determine a resistance of the welding wire within the torch based at least in part on changes to a current and a voltage of a welding waveform, the sensing system is configured to determine an arc length and an electrode extension based at least in part on a functional relationship between the resistance and the electrode extension, and the sensing system is configured to determine the CPWD based at least in part on the arc length and the electrode extension; and a controller coupled to the wire feeder, wherein the controller is configured to control a wire feed speed (WFS) of the wire feeder during an operator-controlled weld based at least in part on the determined CPWD and the input of the operator preference received via the operator interface. 15. The welding system of claim 14 , wherein the sensing system comprises one or more sensors configured to sense the welding waveform applied to the welding wire at the contact point, and the sensing system is configured to determine the CPWD based at least in part on changes to the welding waveform applied to the welding wire at the contact point. 16. The welding system of claim 14 , wherein the welding system comprises an automated welding system, the controller is configured to control a movement of the torch relative to the workpiece, and the controller is configured to control a penetration of a weld into the workpiece based at least in part on the determined CPWD. 17. The welding system of claim 14 , wherein the controller is configured to change the wire feed speed based at least in part on a gain factor entered as the input received via the operator interface. 18. The method of claim 1 , comprising determining an arc length based at least in part on a functional relationship stored in a