Mechanical infinitely variable transmission for outdoor power equipment

What is claimed is: 1. An infinitely variable transmission (IVT), comprising: a planetary gearset comprising a sun gear, two or more planet gears, a carrier, and an annulus gear; an input shaft configured to be rotated by a prime mover at an input angular velocity, wherein the input shaft is configured to drive rotation of the sun gear at a first angular velocity and an input pulley of a pulley system at the first angular velocity, wherein the first angular velocity is based on the input angular velocity; a pulley system comprising the input pulley and an output pulley linked via a belt, wherein one of the input pulley or the output pulley is a variable diameter pulley, and wherein the output pulley is configured to rotate at a second angular velocity, wherein the second angular velocity is based on the first angular velocity and a pulley gear ratio of the pulley system; an actuator configured to receive an input signal and to control a diameter of the variable diameter pulley based on the input signal, wherein the pulley gear ratio is based at least in part on the diameter of the variable diameter pulley; a mixing gear configured to rotate at the second angular velocity, wherein the mixing gear is configured to rotate the annulus gear of the planetary gearset at an annulus angular velocity based on the second angular velocity and a mixing gear ratio between the mixing gear and the outside of the annulus gear, and wherein the carrier is configured to rotate at an output angular velocity that is based on the first angular velocity and the annulus angular velocity; an output gear configured to rotate with the carrier; and a drive element gear coupled to the output gear and configured to be driven by the output gear at a drive angular velocity that is based on the output angular velocity and an output gear ratio between the output gear and the drive element gear, wherein the drive element gear is configured to rotate a drive element at the drive angular velocity. 2. The IVT of claim 1 , wherein the pulley gear ratio ranges between a maximum pulley gear ratio and a minimum pulley gear ratio, wherein when the pulley gear ratio is the maximum pulley gear ratio the output angular velocity is a first maximum output angular velocity in a first direction, wherein when the pulley gear ratio is the minimum pulley gear ratio the output angular velocity is a second maximum output angular velocity in a second direction that is different than the first direction. 3. The IVT of claim 1 , wherein the input shaft is configured to drive a first shaft at the first angular velocity, and wherein the sun gear and the input pulley are coupled to and rotate with the first shaft. 4. The IVT of claim 1 , wherein the first angular velocity has a first magnitude, and wherein the input angular velocity has the first magnitude. 5. The IVT of claim 1 , wherein the variable diameter pulley comprises the actuator. 6. The IVT of claim 1 , wherein the pulley system comprises a moveable pulley, and wherein the actuator is configured to control the diameter of the variable diameter pulley by moving the moveable pulley. 7. The IVT of claim 6 , wherein the actuator is coupled to a rod via an actuator arm, wherein the moveable pulley is coupled to the rod via a pulley arm, and wherein the actuator is configured to move the moveable pulley by rotating the rod. 8. The IVT of claim 1 , wherein the second angular velocity is the product of the first angular velocity and the pulley gear ratio. 9. The IVT of claim 1 , wherein the variable diameter pulley is the output pulley. 10. The IVT of claim 1 , wherein the variable diameter pulley is the input pulley. 11. The IVT of claim 1 , wherein the annulus angular velocity is the product of the second angular velocity and the mixing gear ratio. 12. The IVT of claim 1 , wherein the output pulley and the mixing gear are coupled to and rotate with a first shaft. 13. The IVT of claim 1 , further comprising a speed sensor configured to sense a sensed angular velocity of one of the carrier, the output gear, or the drive element gear, wherein the speed sensor is further configured to output the sensed angular velocity. 14. An outdoor power equipment, comprising: a frame; a prime mover; one or more drive elements coupled to the frame; operator controls configured to receive an operator input comprising a first drive input associated with a first drive element of the one or more drive elements; a control unit configured to determine a commanded output based on the first driver input and to output a control signal based at least in part on the commanded output; a first infinitely variable transmission (IVT) coupled to a first drive element of the one or more drive elements, comprising: a planetary gearset comprising a sun gear, two or more planet gears, a carrier, and an annulus gear; an input shaft configured to be rotated by the prime mover at an input angular velocity, wherein the input shaft is configured to drive rotation of the sun gear at a first angular velocity and an input pulley of a pulley system at the first angular velocity, wherein the first angular velocity is based on the input angular velocity; a pulley system comprising the input pulley and an output pulley linked via a belt, wherein one of the input pulley or the output pulley is a variable diameter pulley, and wherein the output pulley is configured to rotate at a second angular velocity, wherein the second angular velocity is based on the first angular velocity and a pulley gear ratio of the pulley system; an actuator configured to receive an input signal and to control a diameter of the variable diameter pulley based on the input signal, wherein the pulley gear ratio is based at least in part on the diameter of the variable diameter pulley; a mixing gear configured to rotate at the second angular velocity, wherein the mixing gear is configured to rotate the annulus gear of the planetary gearset at an annulus angular velocity based on the second angular velocity and a mixing gear ratio between the mixing gear and the outside of the annulus gear, and wherein the carrier is configured to rotate at an output angular velocity that is based on the first angular velocity and the annulus angular velocity; an output gear configured to rotate with the carrier; and a drive element gear coupled to the output gear and configured to be driven by the output gear at a drive angular velocity that is based on the output angular velocity and an output gear ratio between the output gear and the drive element gear, wherein the drive element gear is configured to rotate the first drive element at the drive angular velocity. 15. The outdoor power equipment of claim 14 , further comprising a speed sensor configured to sense a sensed angular velocity of one of the carrier, the output gear, or the drive element gear, wherein the speed sensor is further configured to output the sensed angular velocity to the control unit. 16. The outdoor power equipment of claim 14 , wherein the control unit is configured to generate the control signal based at least in part on the sensed angular velocity. 17. An infinitely variable transmission (IVT), comprising: a planetary gearset comprising a sun gear having a number of teeth N s , a set of planet gears, a carrier, and an annulus gear having a number of teeth N a ; an input shaft configured to be rotated by a prime mover at an input angular velocity, wherein the input shaft is configured to drive rotation of the sun gear at a first angular velocity, ω 1 , and an input pulley of a pulley sys