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An articulated machine and method of operation, the articulated machine having a first frame with a first traction device and a steering apparatus that controls a steering angle thereof, the first frame pivotally coupled to a second frame at an articulation joint, the second frame having a second tr

An articulated machine and method of operation, the articulated machine having a first frame with a first traction device and a steering apparatus that controls a steering angle thereof, the first frame pivotally coupled to a second frame at an articulation joint, the second frame having a second traction device, a steering sensor configured to provide a steering signal indicative of the steering angle, and an electronic controller configured to automatically control an articulation angle based on the steering signal.

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1. An articulated machine, comprising: a first frame having a first traction device and a steering apparatus operable to control a steering angle of the first traction device;a second frame pivotally coupled to the first frame at an articulation joint, the second frame having a second traction devic

1. An articulated machine, comprising: a first frame having a first traction device and a steering apparatus operable to control a steering angle of the first traction device;a second frame pivotally coupled to the first frame at an articulation joint, the second frame having a second traction device;a steering sensor configured to provide a steering signal indicative of the steering angle; andan electronic controller configured to automatically control an articulation angle of the first frame relative to the second frame based on the steering signal, wherein the electronic controller is configured to limit the steering angle of the first traction device based on a maximum articulation angle. 2. The articulated machine of claim 1, wherein the controller is configured to command an articulation angle to conform a turning radius of the first frame to a turning radius of the second frame. 3. The articulated machine of claim 2, wherein the first traction device includes a first wheel and a second wheel disposed on opposing sides of the first frame, and the turning radius of the first frame is defined by a point equidistant between the first wheel and the second wheel. 4. The articulated machine of claim 3, wherein the second traction device includes a first wheel and a second wheel disposed on opposing sides of the second frame, and the turning radius of the second frame is defined by a point equidistant between the first and second wheels of the second frame. 5. The articulated machine of claim 3, wherein the second traction device includes a first tandem and a second tandem pivotally connected on opposing sides of the second frame, and the turning radius of the second frame is defined by a point equidistant between a pivotal connection of the opposing first and second tandems. 6. The articulated machine of claim 1, further comprising an articulation sensor configured to provide an articulation signal indicative of an articulation angle, the controller further configured to control the articulation angle based on the articulation signal. 7. The articulated machine of claim 1, wherein the controller is configured to provide a communication signal to an operator indicator when the steering angle exceeds a maximum steering angle allowable based on a maximum articulation angle. 8. The articulated machine of claim 1, further comprising a mode selector that provides a mode signal to the controller selecting between an automatic mode, wherein control of the articulation angle by the controller is based on the steering angle, and a manual mode wherein the articulation angle and the steering angle are manually controlled. 9. The machine of claim 8, further comprising a powertrain sensor configured to monitor machine speed, wherein the automatic mode is disengaged when the machine speed is above a desired machine speed. 10. The machine of claim 8, further comprising a transmission sensor configured to monitor a transmission output ratio or gear selection, wherein the automatic mode is disengaged based upon the output ratio or gear selection. 11. The articulated machine of claim 1, wherein the controller is configured to control the articulation angle by calculating a desired articulation angle at which a turning radius of the first frame equals a turning radius of the second frame based on the steering angle, and responsively commanding an actuator to the desired articulation angle. 12. The articulated machine of claim 1, wherein the controller is configured to employ the steering signal in connection with one of a table or map to command the articulation angle. 13. The articulated machine of claim 1, wherein the first traction device includes a first wheel and a second wheel disposed on opposing sides of the first frame, the machine having a first steering sensor associated with the first wheel and a second steering sensor associated with the second wheel, wherein the steering angle is an average steering angle calculated by the controller based on signals received from the first and second steering sensors. 14. A method of operating a motor grader having steerable front wheels and a front and rear frame pivotally connected at an articulation joint, comprising: selecting an automatic articulation mode; propelling the motor grader along a direction of travel;commanding front wheel steering to turn the motor grader;and providing a front wheel steering signal to an electronic controller, the electronic controller automatically commanding articulation of the front frame relative to the rear frame about the articulation joint in response to the front wheel steering signal, wherein the front wheel steering signal is indicative of a front wheel steering angle and the front wheel steering angle is limited based upon a maximum allowable articulation angle. 15. The method of claim 14, wherein the controller being configured to command an articulation angle that conforms a turning radius of the front frame to a turning radius of the rear frame based upon the steering angle. 16. The method of claim 14, wherein the controller derives the commanded articulation by comparing the front wheel steering angle to a table or map stored in a memory of the controller. 17. The method of claim 14, further comprising providing a travel speed, transmission gear, or transmission output ratio signal to the controller, the controller determining whether or not to command articulation based upon the travel speed, transmission gear or transmission output ratio. 18. A motor grader, comprising: a front frame having a first and second steerable wheel disposed on opposing sides of the frame;a rear frame pivotally coupled to the front frame at an articulation joint, a first and second articulation cylinder disposed between the front and rear frames in opposing orientation, the rear frame having a tandem with two rear wheels pivotally connected on opposing sides of the rear frame;a steering sensor configured to provide a steering signal indicative of a steering angle of the first and second steerable wheels; andan electronic controller configured to automatically command the first and second articulation cylinders to control an articulation angle of the first frame relative to the rear frame based on the steering angle, wherein the controller is configured to limit the steering angle of the first and second steerable wheel based on a maximum articulation angle.