Systems and methods for controlling ground inclination of rotary cutting machines

What is claimed is: 1. A machine for road work, the machine comprising: a frame; a plurality of ground engaging units; a plurality of vertically moveable legs, each leg connecting one of the plurality of ground engaging units to the frame; a pair of spatial sensors, each spatial sensor of the pair of spatial sensors configured to generate an output signal representing a three-dimensional position obtained from a satellite navigation or positioning system; and a controller configured to, in response to the output signal received from each of the spatial sensors, activate at least some of the plurality of vertically moveable legs to control slope of the frame to remain within a tolerance band of a selected attitude, the tolerance band selected to maintain stability of the machine for road work. 2. The machine for road work of claim 1 , wherein the pair of spatial sensors comprise a pair of GNSS sensors coupled to the frame. 3. The machine for road work of claim 2 , wherein the pair of spatial sensors are located on diagonal corners of the frame. 4. The machine for road work of claim 1 , further comprising one or more slope sensors configured to sense a rotational orientation of the frame, wherein each of the one or more slope sensors comprises a dual-axis sensor configured to provide a cross-check to the output signals of the pair of spatial sensors. 5. The machine for road work of claim 4 , wherein the one or more slope sensors are coupled to the frame. 6. The machine for road work of claim 1 , further comprising position sensors coupled to the plurality of vertically moveable legs configured to sense a length of each of the plurality of vertically moveable legs. 7. The machine for road work of claim 1 , further comprising propulsor sensors coupled to the plurality of ground engaging units configured to sense an orientation of each of the ground engaging units relative to a vertically moveable leg to which each of the ground engaging units is attached. 8. The machine for road work of claim 1 , wherein the controller is configured to activate at least some of the plurality of vertically moveable legs to level the frame. 9. The machine for road work of claim 1 , wherein the controller is configured to activate at least some of the plurality of vertically moveable legs to maintain the attitude of the frame within the tolerance band that comprises a stable orientation of the machine for road work that prevents roll-over, wherein the tolerance band is calculated relative to an inclined surface being traversed by the machine for road work to maintain stability in front-to-back and left-to-right orientations. 10. The machine for road work of claim 1 , wherein the controller is configured to, in response to sensing a change in a cross slope of the machine, activate at least one of the plurality of vertically moveable legs to move up and an opposite one of the plurality of vertically moveable legs to move down. 11. The machine for road work of claim 1 , wherein the controller is configured to activate all of the plurality of vertically moveable legs in real-time. 12. The machine for road work of claim 1 , wherein the controller is configured to activate the at least some of the plurality of vertically moveable legs while a milling assembly mounted to the frame is in a non-operating state. 13. A method of maintaining attitude of a construction machine having a propulsion system including multiple independent propulsors, the method comprising: traversing a ground surface having a changing topography with the multiple independent propulsors; sensing changing slope of the construction machine using at least one pair of spatial sensors attached to the construction machine, each spatial sensor of the at least one pair of spatial sensors configured to generate an output signal representing a three-dimensional position obtained from a satellite navigation or positioning system, wherein changing slope of the construction machine is sensed by comparing the output signal of each spatial sensor of the at least one pair of spatial sensors to each other; calculating a deviation of an attitude of the machine from a selected attitude by comparing the sensed changing slope of the construction machine determined from the output signals of both of the at least one pair of spatial sensors to the selected attitude; and adjusting a height of at least one of the multiple independent propulsors to return the attitude of the machine to within a tolerance band of the selected attitude. 14. The method of claim 13 , wherein the selected attitude comprises an orientation relative to an operator located on the construction machine. 15. The method of claim 13 , wherein the selected attitude comprises a stable orientation of the construction machine that prevents roll-over. 16. The method of claim 13 , wherein adjusting the height of the multiple independent propulsors to return the attitude of the machine to the selected attitude occurs in real-time. 17. The method of claim 13 , wherein adjusting the height of the multiple independent propulsors to return the attitude of the machine to the selected attitude occurs while a milling assembly mounted to the construction machine is in a non-operating state. 18. The method of claim 13 , wherein sensing changing slope of the construction machine includes using a slope sensor in combination with at least one pair of GNSS sensors comprising the at least pair of spatial sensors, and the slope sensor is attached to the construction machine. 19. The method of claim 13 , wherein sensing changing slope of the construction machine includes using a position sensor in combination with at least one pair of GNSS sensors comprising the at least one pair of spatial sensors, and the position sensor is configured to sense a length of a lifting column attached to one of the multiple independent propulsors. 20. The method of claim 13 , wherein sensing changing slope of the construction machine includes using an orientation sensor in combination with at least one pair of GNSS sensors comprising the at least one pair of spatial sensors, and the orientation sensor is configured to sense an orientation of one of the multiple independent propulsors relative to a lifting column attached to the one of the multiple independent propulsors.