Winch with one-way reverse tensioner

We claim: 1. A winch, comprising: a drum that draws in and lets out a line; a motor and transmission that apply torque to the drum; and a tensioner positioned adjacent to the drum such that when the line passes between the tensioner and drum, the line is in frictional contact with the tensioner and drum, wherein the tensioner rotates with a linear speed exceeding a linear speed of the drum as the line is let out from the drum such that the line is pulled tight around the drum as the line pays out, and wherein the tensioner rotates freely as the line is drawn in; wherein the tensioner is driven by a tensioner motor; winch microcontroller wired to the winch motor; a tensioner microcontroller wired to the tensioner motor; wherein the winch microcontroller reads a rotation rate of the winch drum and communicates the rotation rate to the tensioner microcontroller; using stored data the tensioner microcontroller uses the rotation rate of the winch drum to determine a rotation rate of tensioner that results in a linear speed of tensioner greater than the linear speed of the drum as the line is let out from the drum. 2. The winch of claim 1 , wherein the tensioner comprises a one-way bearing. 3. The winch of claim 1 , wherein the motor and transmission are contained at least partially within the drum. 4. The winch of claim 3 , wherein the motor and transmission are fully contained within the drum. 5. The winch of claim 1 , wherein the drum comprises a gear that engages a tensioner gear. 6. The winch of claim 4 , further comprising a drum gear attached to the drum, and a tensioner gear attached to the tensioner, wherein the drum gear rotates at the same speed as the drum, and wherein the tensioner gear rotates at the same speed as the tensioner. 7. The winch of claim 6 , wherein the drum gear has a gear ratio with the tensioner gear ranging from 1.1 turns of the gear ration for every 1 turn of the drum gear, to 100 turns of the gear ratio for every 1 turn of the drum gear. 8. The winch of claim 6 , wherein the drum gear has a gear ratio with the tensioner gear ranging from 1.1:1 to 25:1, 25:1 to 50:1, 50:1 to 75:1, 75:1 to 100:1, 1.1:1 to 10:1, 10:1 to 20:1, 20:1 to 30:1, 30:1 to 40:1, 40:1 to 50:1, 50:1 to 60:1, 60:1 to 70:1, 70:1 to 80:1, 80:1 to 90:1, or 90:1 to 100:1. 9. The winch of claim 1 , wherein the tensioner comprises one or more of a wheel, a sphere, and a belt. 10. The winch of claim 8 , wherein the tensioner wheel comprises a groove that fits around the line. 11. The winch of claim 1 , wherein the tensioner motor is disposed within a line guide coupled to the winch. 12. A method of using a winch, comprising: providing a winch, wherein the winch comprises a drum that draws in and lets out a line, a motor and transmission that apply torque to the drum, and a tensioner positioned adjacent to the drum such that when the line passes between the tensioner and drum, the line is in frictional contact with the tensioner and drum, wherein the tensioner rotates with a linear speed exceeding a linear speed of the drum as the line is let out from the drum, and wherein the tensioner rotates freely as the line is drawn in; wherein the line passes between the tensioner and the drum; and causing the winch to rotate; wherein a tensioner motor for driving the tensioner; a winch microcontroller wired to the winch motor; a tensioner microcontroller wired to the tensioner motor; wherein the winch microcontroller reads a rotation rate of the winch drum and communicates the rotation rate to the tensioner microcontroller; using stored data the tensioner microcontroller uses the rotation rate of the winch drum to determine a rotation rate of tensioner that results in a linear speed of tensioner greater than the linear speed of the drum as the line is let out from the drum. 13. A method of making a winch, comprising: providing a drum; coupling a motor and transmission to the drum, wherein the motor and transmission apply torque to the drum; and coupling a tensioner to the drum, such that when a line passes between the tensioner and drum, the line is in frictional contact with the tensioner and drum, and such that the tensioner rotates with a linear speed exceeding a linear speed of the drum as the line is let out from the drum, and such that the tensioner rotates freely as the line is drawn in; wherein a tensioner motor for driving the tensioner; a winch microcontroller wired to the winch motor; a tensioner microcontroller wired to the tensioner motor; wherein the winch microcontroller reads a rotation rate of the winch drum and communicates the rotation rate to the tensioner microcontroller; using stored data the tensioner microcontroller uses the rotation rate of the winch drum to determine a rotation rate of tensioner that results in a linear speed of tensioner greater than the linear speed of the drum as the line is let out from the drum. 14. The method of claim 13 , wherein the motor and transmission are positioned at least partially within the drum.