Split ring carrier with eccentric pin with spring compliance and speed dependence

What is claimed is: 1 . A method of removing backlash from a planetary gear reducer of an engine, the planetary gear reducer comprising a sun gear, a ring gear around the sun gear, and a plurality of planetary gears connected to a planet carrier by pins, the planetary gears meshing with the sun gear and the ring gear, the method comprising the steps of: providing a centrifugally actuated device coupled to a pin of at least one of planetary gears, such that radially inward movement of a first end of the centrifugally actuated device moves the planetary gear in a first direction which minimizes backlash between the planetary gear and the ring gear; biasing the first end of the centrifugally actuated device radially inward toward the planet carrier, such that the planetary gear is moved in the first direction; and rotating the planet carrier at a rotational speed sufficient to overcome the biasing, causing centrifugal force to move the end of the centrifugally actuated device radially outward, moving the planetary gear in a direction opposite the first direction. 2 . The method of claim 1 , wherein the centrifugally actuated device comprises an extension arm with a first end with a mass, a second end pivotally coupled to the pin of the at least one planetary gear, and a length therebetween. 3 . The method of claim 1 , in which the pin coupled to the centrifugally actuated device is an eccentric pin having a cylindrical shape. 4 . An electric phaser for dynamically adjusting a rotational relationship of a first shaft relative to a second shaft of an engine, comprising: a planetary gear reducer comprising: a sun gear comprising a plurality of sun gear teeth; a plurality of planetary gears arranged around the sun gear, each planetary gear comprising a plurality of planetary teeth maintaining the planetary gear in meshing engagement with the sun gear teeth; a planet carrier being rotatable with the plurality of planetary gears and connected to the planetary gears through pins; a ring gear with a set of teeth fixed to the second shaft; a centrifugally actuated device comprising an extension arm with a first end with a mass, a second end pivotally coupled to the pin of the at least one planetary gear, and a length therebetween, such that radially inward movement of the first end of the centrifugally actuated device moves the planetary gear in a first direction which minimizes backlash between the planetary gear and the ring gear; and a load generator coupled to the planet carrier and the centrifugally actuated device, biasing the first end of the centrifugally actuated device radially inward; such that when the planet carrier is rotating at a rotational speed less than a speed sufficient to overcome the biasing of the load generator, the at least one planetary gear is moved by the centrifugally actuated device to minimize backlash between the planetary gears and the ring gear, and when the planet carrier is rotated at a higher rotational speed, centrifugal force moves the first end of the centrifugally actuated device radially outward, moving the planetary gear in a direction opposite the first direction. 5 . The electric phaser of claim 4 , wherein the centrifugally operated device further comprises: an eccentric pin having a cylindrical shape, the eccentric pin extending through a center of the at least one of the planetary gear of the plurality of planetary gears and connected to the second end of the extension arm; and a pair of pin extensions extending from a top and a bottom of the eccentric pin and having circumferential surfaces off-center with respect to a center of the cylindrical surface of the eccentric pin, wherein the pin extensions rotatably mount in the carrier such that the centrifugally actuated device is rotatable with respect to the planet carrier and with respect to the planetary gear teeth of the at least one planetary gear; when the planet carrier is rotating at a rotational speed less than a speed sufficient to overcome the biasing of the load generator, the eccentric pin forces the at least one planetary gear toward the ring gear to minimize backlash between the at least one planetary gear and the ring gear. 6 . The electric phaser of claim 5 , wherein when the planet carrier is rotated at a higher rotational speed, centrifugal force moves the first end of the extension arm radially outward, simultaneously rotating the eccentric pin to a pin position where the eccentric pin no longer forces the at least one planetary gear toward the ring gear to take up the backlash. 7 . The electric phaser of claim 4 , further comprising a stop extending from the planet carrier, limiting rotation of the centrifugally actuated device from contacting the ring gear. 8 . An electric phaser for dynamically adjusting a rotational relationship of a first shaft relative to a second shaft of an engine, comprising: a planetary gear reducer comprising: a sun gear comprising a plurality of sun gear teeth; a plurality of planetary gears arranged around the sun gear, each planetary gear comprising a plurality of planetary teeth maintaining the planetary gear in meshing engagement with the sun gear teeth; a planet carrier being rotatable with the plurality of planetary gears and connected to the planetary gears through pins; a second ring gear rotatable with a second shaft, the second ring gear comprising a plurality of second ring gear teeth maintaining the second ring gear in meshing engagement with the planetary gear teeth of each of the planetary gears; a first ring gear rotatable with a first shaft, the first ring gear comprising a plurality of first ring gear teeth maintaining the first ring gear in meshing engagement with the planetary gear teeth of each of the planetary gears; a centrifugally actuated device comprising an extension arm with a first end with a mass, a second end pivotally coupled to the pin of the at least one planetary gear, and a length therebetween, such that radially inward movement of the first end of the centrifugally actuated device moves the planetary gear in a first direction which minimizes backlash between the planetary gear and the ring gear; and a load generator coupled to the planet carrier and the centrifugally actuated device, biasing the first end of the centrifugally actuated device radially inward; such that when the planet carrier is rotating at a rotational speed less than a speed sufficient to overcome the biasing of the load generator, the at least one planetary gear is moved by the centrifugally actuated device to minimize backlash between the planetary gears and the ring gear, and when the planet carrier is rotated at a higher rotational speed, centrifugal force moves the first end of the centrifugally actuated device radially outward, moving the planetary gear in a direction opposite the first direction. 9 . The electric phaser of claim 8 , wherein the centrifugally operated device further comprises: an eccentric pin having a cylindrical shape, the eccentric pin extending through a center of the at least one of the planetary gear of the plurality of planetary gears and connected to the second end of the extension arm; and a pair of pin extensions extending from a top and a bottom of the eccentric pin and having circumferential surfaces off-center with respect to a center of the cylindrical surface of the eccentric pin, wherein the pin extensions rotatably mount in the carrier such that the centrifugally actuated device is rotatable with respect to the planet carrier and with respect to the planetary gear teeth of the at least one planetary gear; when the planet carrier is rotating at a rotational speed less than a speed sufficient to overcome the biasing of the lo