Transfer case for a drive train

What is claimed is: 1. A transfer case for a drive train, comprising: a transfer case input shaft configured to rotatably engage with a power source; a sun gear circumscribing at least a portion of the transfer case input shaft, and including a collar end and a gear end opposite the collar end; a hub circumscribing the collar end and at least a portion of the transfer case input shaft, and configured to slidably move between a first position and a second position opposite the first position along the transfer case input shaft and the collar end; a plurality of planetary gears mounted in a carrier body circumscribing the gear end, the carrier body being splined with the transfer case input shaft; and a ring gear circumscribing the plurality of planetary gears mounted in the carrier body integrally joined with a transfer case rear output shaft, the ring gear rotatable around the plurality of planetary gears mounted in the carrier body, the transfer case rear output shaft configured to rotatably couple with a rear drive shaft. 2. The transfer case according to claim 1 , wherein while the hub is in the first position the sun gear is locked to the transfer case input shaft thereby causing the transfer case rear output shaft to rotate at the same speed as the transfer case input shaft. 3. The transfer case according to claim 1 , wherein while the hub is in the first position the sun gear is locked to the transfer case input shaft and power from the power source is conveyed between the transfer case input shaft and the transfer case rear output shaft through the hub, the sun gear, the plurality of planetary gears mounted in the carrier body, and the ring gear. 4. The transfer case according to claim 1 , wherein while the hub is in the second position the sun gear is locked to a transfer case housing thereby causing the transfer case rear output shaft to rotate at a greater speed than the transfer case input shaft. 5. The transfer case according to claim 1 , wherein while the hub is in the second position the sun gear is locked to a transfer case housing and power from the power source is conveyed between the transfer case input shaft and the transfer case rear output shaft through the carrier body, the plurality of planetary gears mounted in the carrier body, and the ring gear. 6. The transfer case according to claim 1 , wherein while the hub is located between the first position and the second position, the sun gear is locked to neither the transfer case input shaft nor a transfer case housing thereby disengaging the transfer case input shaft from the transfer case rear output shaft. 7. A drive train, comprising: a power source; a transmission rotationally coupled with the power source configured to convert power of the power source to a selectively geared output; and a transfer case rotatably coupled to the transmission via a transfer case input shaft including a sun gear circumscribing at least a portion of the transfer case input shaft and including a collar end and a gear end opposite the collar end, a hub circumscribing the collar end and at least a portion of the transfer case input shaft, and configured to slidably move between a first position and a second position opposite the first position along the transfer case input shaft and the collar end, a plurality of planetary gears mounted in a carrier body circumscribing the gear end, the carrier body being splined with the transfer case input shaft, and a ring gear circumscribing the plurality of planetary gears mounted in the carrier body integrally joined with a transfer case rear output shaft, the ring gear rotatable around the plurality of planetary gears mounted in the carrier body. 8. The drive train according to claim 7 , wherein while the hub is in the first position the sun gear is locked to the transfer case input shaft thereby causing the transfer case rear output shaft to rotate at the same speed as the transfer case input shaft. 9. The drive train according to claim 7 wherein while the hub is in the first position the sun gear is locked to the transfer case input shaft and power from the power source is conveyed between the transfer case input shaft and the transfer case rear output shaft through the hub, the sun gear, the plurality of planetary gears mounted in the carrier body, and the ring gear. 10. The drive train according to claim 7 , wherein while the hub is in the second position the sun gear is locked to a transfer case housing thereby causing the transfer case rear output shaft to rotate at a greater speed than the transfer case input shaft. 11. The drive train according to claim 7 , wherein while the hub is in the second position the sun gear is locked to a transfer case housing and power from the power source is conveyed between the transfer case input shaft and the transfer case rear output shaft through the carrier body, the plurality of planetary gears mounted in the carrier body, and the ring gear. 12. The drive train according to claim 7 , wherein while the hub is located between the first position and the second position, the sun gear is locked to neither the transfer case input shaft nor a transfer case housing thereby disengaging the transfer case input shaft from the transfer case rear output shaft. 13. A method of operating a transfer case for a drive train, comprising: slidably moving a hub to a first position thereby locking a sun gear to a transfer case input shaft, the hub configured to slidably move between the first position and a second position opposite the first position along the transfer case input shaft; rotating the transfer case input shaft; conveying power from the transfer case input shaft to a transfer case rear output shaft through the hub, the sun gear, a plurality of planetary gears mounted in a carrier body, and a ring gear integrally joined with the transfer case rear output shaft. 14. The method of claim 13 , slidably moving the hub to a second position thereby locking the sun gear to a transfer case housing, rotating the transfer case input shaft, and conveying power from the transfer case input shaft to the transfer case rear output shaft through a carrier body, the plurality of planetary gears mounted in the carrier body, and the ring gear integrally joined with the transfer case rear output shaft. 15. The method of claim 13 , slidably moving the hub to a location between the first position and a second position thereby unlocking the sun gear from both the transfer case input shaft and a transfer case housing and disengaging the transfer case input shaft from the transfer case rear output shaft.