System and method for operating a three-dimensional printer to compensate for radial velocity variations

What is claimed: 1. A three-dimensional object printer comprising: a platen configured to rotate about a center; a first actuator operatively connected to the platen, the first actuator being configured to rotate the platen; a radial arm that extends from a position proximate the center of the platen to a position proximate a circumferential edge of the platen; at least one printhead mounted to the radial arm, the at least one printhead being configured to eject material onto the platen as the platen rotates past the at least one printhead; a second actuator operatively connected to the at least one printhead, the second actuator being configured to move the at least one printhead along the radial arm and to change an angle between the at least one printhead and the radial arm; and a controller operatively connected to the at least one printhead, the first actuator, and the second actuator, the controller being configured to: operate the first actuator to rotate the platen; operate the at least one printhead to eject material onto the platen as the platen rotates past the at least one printhead; and adjust operation of the first actuator to change an angular velocity of the platen or adjust operation of the second actuator to change a velocity of the at least one printhead along the radial arm or an angle between the at least one printhead and the radial arm to maintain a density of the material ejected onto a portion of the rotating platen nearer a center of the platen constant with a density of the material ejected onto a portion of the rotating platen nearer a circumferential edge of the platen. 2. The printer of claim 1 , the controller being further configured to: adjust operation of the second actuator to move the at least one printhead along the radial arm between a position nearer the center of the platen and a position nearer the circumferential edge of the platen at a velocity that enables a product of a radial distance of the at least one printhead from the center of the platen and the angular velocity of the platen to remain constant as the at least one printhead moves between a position nearer the center of the rotating platen and a position nearer the circumferential edge of the rotating platen. 3. The three-dimensional object printer of claim 2 , the controller being further configured to: operate the first actuator to rotate the platen at a predetermined angular velocity; and adjust operation of the second actuator to reduce the velocity of the at least one printhead as the at least one printhead moves towards the position nearer the circumferential edge of the platen to maintain the product of the radial distance of the at least one printhead from the center of the platen and the angular velocity of the platen constant as the at least one printhead moves towards the position nearer the circumferential edge of the rotating platen. 4. The three-dimensional object printer of claim 2 , the controller being further configured to: operate the first actuator to rotate the platen at a predetermined angular velocity; and adjust operation of the second actuator to increase the velocity of the at least one printhead as the at least one printhead moves towards the position nearer the center of the platen to maintain the product of the radial distance of the at least one printhead from the center of the platen and the angular velocity of the platen constant as the at least one printhead moves towards the position nearer the center of the rotating platen. 5. The three-dimensional object printer of claim 1 , the controller being further configured to: adjust operation of the first actuator to adjust the angular velocity of the rotating platen as the at least one printhead moves between a position nearer the center of the platen and a position nearer the circumferential edge of the platen to maintain a product of a radial distance of the at least one printhead from the center of the platen and the angular velocity of the platen constant as the at least one printhead moves between the position nearer the center of the platen and the position nearer the circumferential edge of the rotating platen. 6. The three-dimensional object printer of claim 5 , the controller being further configured to: adjust operation of the first actuator to increase the angular velocity of the rotating platen as the at least one printhead moves from the position nearer the circumferential edge of the platen towards the position nearer the center of the platen to maintain the product of the radial distance of the at least one printhead from the center of the platen and the angular velocity of the platen constant as the at least one printhead moves towards the position nearer the center of the rotating platen. 7. The three-dimensional object printer of claim 5 , the controller being further configured to: adjust operation of the first actuator to decrease the angular velocity of the rotating platen as the at least one printhead moves from the position nearer the center of the platen towards the position nearer the circumferential edge of the platen to maintain the product of the radial distance of the at least one printhead from the center of the platen and the angular velocity of the platen constant as the at least one printhead moves towards the position nearer the circumferential edge of the rotating platen. 8. The three-dimensional object printer of claim 1 , the controller being further configured to: adjust operation of the second actuator to rotate the at least one printhead with respect to the radial arm to increase an angle between the at least one printhead and the radial arm as the at least one printhead moves towards the circumferential edge of the platen. 9. The three-dimensional object printer of claim 1 , the controller being further configured to: adjust operation of the second actuator to rotate the at least one printhead with respect to the radial arm to decrease an angle between the at least one printhead and the radial arm as the at least one printhead moves towards the center of the platen. 10. The three-dimensional object printer of claim 5 , the controller being further configured to: generate data for operating the at least one printhead from image data corresponding to an object to be produced by the three-dimensional object printer, the data for operating the at least one printhead corresponding to a plurality of cylinders concentric with the center of the platen; and operate the first actuator and the second actuator with reference to the generated data. 11. The three-dimensional object printer of claim 10 , the controller being further configured to: generate the data for operating the at least one printhead to enable a product of a radial position of a circumference of each cylinder and a change in circumference between a previous cylinder and a current cylinder being a constant. 12. The three-dimensional object printer of claim 1 , the at least one printhead being configured as at least two printheads mounted to the radial arm, the inkjets within each of the at least two printheads being separated from one another in a direction aligned with the radial arm by a same distance, one of the at least two printheads being nearer the center of the platen and being aligned with the radial arm and another of the least two printheads being nearer the circumferential edge and being at an angle with reference to the radial arm to enable the inkjets in the other printhead nearer the circumferential edge to eject material drops at a density constant with a density for the material drops ejected by the printhead nearer the center of the platen.