Cutting Tool Visual Trajectory Representation System and Method

We claim: 1 . A machine, comprising: a frame; a plurality of ground engaging members, the plurality of ground engaging members configured to move the machine along a ground surface at a machine speed and to steer the machine relative to the ground surface at a steering angle; a machine speed sensor providing a machine speed signal indicative of the machine speed; a steering sensor providing a steering signal indicative of the steering angle; a work implement connected to the frame, the work implement operating to cut at least a portion of the ground surface as the machine moves along the ground surface; at least one camera associated with the frame, the at least one camera arranged to capture a video image of a viewed area and to provide a video signal related to the viewed area; a video display associated with an operator cab of the machine; and an electronic controller associated with the frame, the electronic controller being programmed and configured to: receive the machine speed signal, the steering signal and the video signal; determine a current position of the work implement relative to the frame and relative to the viewed area in real time; compile a visual display in which the current position and a current direction of the work implement relative to the viewed area is displayed in real time; calculate a trajectory of the work implement based on the machine speed signal and the steering signal; compile a visual trajectory representation of the trajectory of the work implement relative to the viewed area; combine the visual display and the visual trajectory representation into a combined visual representation; and provide the combined visual representation to the video display. 2 . The machine of claim 1 , wherein the plurality of ground engaging members is a set of four tracks arranged in two pairs of tracks, each pair of tracks arranged across a corresponding one of two axles of the frame, and wherein each of the two pairs of tracks is selectively steerable in unison relative to the frame in response to an operator command such that a resulting compound angle changes a path of the machine along the ground surface. 3 . The machine of claim 1 , further comprising an enclosure connected to the frame, wherein the work implement is a milling drum that is rotatably mounted to the frame and disposed within the enclosure. 4 . The machine of claim 3 , wherein the operator cab is mounted to the frame at a location above the enclosure such that the milling drum is not readily visible to an operator of the machine when the operator occupies the operator cab. 5 . The machine of claim 1 , further comprising a plurality of cameras, wherein the at least one camera is one of the plurality of cameras and wherein each of the plurality of cameras is configured to view a corresponding viewed area and provide a corresponding video signal from a plurality of video signals to the electronic controller. 6 . The machine of claim 5 , wherein adjacent corresponding viewed areas at least partially overlap, and wherein the electronic controller is further programmed and configured to stitch together two or more corresponding viewed areas into different perspective views around the machine. 7 . The machine of claim 6 , wherein the video display is configured to show any one of the different perspective views. 8 . A cold planer including a frame, a plurality of ground engaging members configured to move the cold planer along a work surface at a machine speed and to steer the cold planer relative to the work surface at a steering angle, the cold planer further comprising: a machine speed sensor providing a machine speed signal indicative of the machine speed; a steering sensor providing a steering signal indicative of the steering angle; a milling drum rotatably supported on the frame; at least one camera associated with the frame, the at least one camera arranged to capture a video image of a viewed area and to provide a video signal related to the viewed area; an operator cab; a video display associated with the operator cab; and an electronic controller associated with the frame, the electronic controller being programmed and configured to: receive the machine speed signal, the steering signal and the video signal; determine a current position of the milling drum relative to the frame and relative to the viewed area in real time; compile a visual display in which the current position and a current direction of the milling drum relative to the viewed area is displayed in real time as a vector; calculate a trajectory of the milling drum based on the machine speed signal and the steering signal; compile a visual trajectory representation of the trajectory of the milling drum relative to the viewed area as a curve; combine the visual display and the visual trajectory representation into a combined visual representation; and provide the combined visual representation to the video display. 9 . The cold planer of claim 8 , wherein the plurality of ground engaging members is a set of four tracks arranged in two pairs of tracks, each pair of tracks arranged across a corresponding one of two axles of the frame, and wherein each of the two pairs of tracks is selectively steerable in unison relative to the frame in response to an operator command such that a resulting compound angle changes a path of the cold planer along the work surface. 10 . The cold planer of claim 8 , further comprising an enclosure connected to the frame, wherein the milling drum is disposed within the enclosure. 11 . The cold planer of claim 10 , wherein the operator cab is mounted to the frame at a location above the enclosure such that the milling drum is not readily visible to an operator of the cold planer when the operator occupies the operator cab. 12 . The cold planer of claim 8 , further comprising a plurality of cameras, wherein the at least one camera is one of the plurality of cameras and wherein each of the plurality of cameras is configured to view a corresponding viewed area and provide a corresponding video signal from a plurality of video signals to the electronic controller. 13 . The cold planer of claim 12 , wherein adjacent corresponding viewed areas at least partially overlap, and wherein the electronic controller is further programmed and configured to stitch together two or more corresponding viewed areas into different perspective views around the cold planer. 14 . The cold planer of claim 13 , wherein the video display is configured to show any one of the different perspective views. 15 . A method for operating a cold planer, comprising: providing a frame; providing a plurality of ground engaging members, the plurality of ground engaging members configured to move the cold planer along a ground surface at a cold planer speed and to steer the cold planer relative to the ground surface at a steering angle; providing a cold planer speed sensor providing a cold planer speed signal indicative of the cold planer speed; providing a steering sensor providing a steering signal indicative of the steering angle; providing a work implement connected to the frame, the work implement operating to cut at least a portion of the ground surface as the cold planer moves along the ground surface; providing at least one camera associated with the frame, the at least one camera arranged to capture a video image of a viewed area and to provide a video signal related to the viewed area; providing a video display associated with an operator cab of the cold planer; and using an electronic controller as