Vibration resistant cable

What is claimed is: 1. A vibration resistant cable comprising: a first conductor having a diameter d; and a second conductor having the diameter d, the second conductor twisted around the first conductor at a lay length between 3 feet and 6 feet to eliminate bagging of the vibration resistant cable during installation; wherein: the first conductor comprises six first aluminum strands surrounding a first core steel strand, and the second conductor comprises six second aluminum strands surrounding a second steel core strand; and the lay length is varying. 2. The vibration resistant cable of claim 1 , wherein an optimum lay length is a function of the diameter d. 3. The vibration resistant cable of claim 1 , wherein an optimum lay length is determined by the equation, c 1 d+c 2 , wherein c 1 and c 2 are constants configured to obtain a locking force to eliminate bagging in the vibration resistant cable and to provide Aeolian vibration dampening in the vibration resistant cable. 4. The vibration resistant cable of claim 1 , wherein the diameter d is equal to about 0.281 inches. 5. The vibration resistant cable of claim 1 , wherein the first core steel strand has a diameter equal to about 0.0937 inches. 6. The vibration resistant cable of claim 5 , wherein the second core steel strand has a diameter equal to about 0.0937 inches. 7. The vibration resistant cable of claim 1 , wherein the vibration resistant cable is not under tension in a power line. 8. The vibration resistant cable of claim 1 , wherein the lay length is further configured to cause a locking force between the first conductor and the second conductor to reduce relative movement. 9. The vibration resistant cable of claim 1 , wherein the lay length is further configured to allow some relative movement between the first conductor and the second conductor to provide Aeolian vibration dampening in the vibration resistant cable. 10. A vibration resistant cable comprising: a first conductor comprising a plurality of first strands surrounding a first core steel strand; and a second conductor comprising a plurality of second strands surrounding a second core steel strand, the second conductor twisted around the first conductor at a lay length that is based at least in part on a locking force of the first conductor or the second conductor; wherein the locking force comprises a compressive spring force based at least in part on a first spring rate associated with the first conductor or a second spring rate associated with the second conductor, the locking force preventing bagging in the first conductor or the second conductor; and wherein bagging results from a relative movement between the first conductor and the second conductor caused at least in part by sheave pushback during installation of the vibration resistant cable. 11. The vibration resistant cable of claim 10 , wherein the plurality of first strands comprises six aluminum strands. 12. The vibration resistant cable of claim 10 , wherein the plurality of second strands comprises six aluminum strands. 13. The vibration resistant cable of claim 10 , wherein the first conductor and the second conductor have a diameter d that is equal to about 0.281 inches. 14. The vibration resistant cable of claim 10 , wherein the first core steel strand has a diameter equal to about 0.0937 inches. 15. The vibration resistant cable of claim 14 , wherein the second core steel strand has a diameter equal to about 0.0937 inches. 16. The vibration resistant cable of claim 10 , wherein the lay length is 3 feet+/−10%. 17. The vibration resistant cable of claim 10 , wherein the vibration resistant cable is not under tension in a power line. 18. The vibration resistant cable of claim 10 , wherein the lay length is varying.