GNSS and optical guidance and machine control

Having thus described the invention, what is claimed as new and desired to be secured by Letters Patent is: 1. A guidance system for a vehicle having optical sensors and a working component attached to the vehicle having optical targets, the guidance system comprising: a guidance computer to: receive inputs from the optical sensors associated with optical signals generated from the optical targets on the working component; and calculate at least one of a roll (X) directional misalignment, pitch (Y) directional misalignment, or yaw (Z) directional misalignment of the working component in relation to an orientation of the vehicle based on the inputs from the optical sensors. 2. The guidance system of claim 1 , wherein the guidance computer is further configured to: receive global navigation satellite system (GNSS) based ranging signals from different antennas located on the vehicle or located on the working component indicating relative positions of the antennas; determine signal quality characters of the ranging signals; and select different combinations of the antennas for receiving the ranging signals based on the signal quality characteristics. 3. The guidance system of claim 2 , wherein the guidance computer is further configured to transfer the ranging signals to said external computer. 4. The guidance system of claim 1 , wherein the vehicle comprises a tractor and the working component comprises an agricultural implement. 5. The guidance system of claim 1 , wherein the vehicle comprises earth-moving equipment and the working component comprises a ground-engaging tool. 6. A navigation computer configured for controlling a vehicle and auxiliary equipment, the computer comprising: a processor to: identify a fixed separation baseline between a first set of antennas on the vehicle; determine multiple variable separation baselines extending between the first set of antennas on the vehicle and a second set of antennas on the auxiliary equipment, the variable separation baselines having variable lengths corresponding to relative variable orientations of the vehicle with the auxiliary equipment; and compute positions of the vehicle and the auxiliary equipment based on the fixed separation baseline and the variable separation baselines, wherein the variable separation baselines identify a roll (X), pitch (Y), or yaw (Z) of the auxiliary equipment relative to a roll (X), pitch (Y), or yaw (Z) of the vehicle. 7. The navigation computer of claim 6 , wherein the processor is preprogrammed with a guide path of movement for the auxiliary equipment. 8. The navigation computer of claim 7 , wherein the processor is further to: calculate a cross-track error between the guide path and the auxiliary equipment based on the variable separation baselines; and compute a vehicle position to correct the cross-track error. 9. The navigation computer of claim 6 , wherein the processor is further to: receive inertial measurement unit (IMU) signals indicating a roll (X), pitch (Y), and yaw (Z) of the auxiliary equipment relative to the vehicle; and compute corrections for the guide path based on the IMU signals. 10. The navigation computer of claim 6 , wherein the processor is further to receive inputs from sensors on the vehicle associated with optical signals generated by the sensors from optical targets on the auxiliary equipment, the optical signals detecting roll (X), pitch (Y), and/or yaw (Z) directional misalignments of the auxiliary equipment in relation to the vehicle. 11. The navigation computer of claim 6 , further comprising the processor to: receive global navigation satellite system (GNSS) based ranging signals from the first and second set of antennas; determine signal quality characters of the ranging signals; and select different combinations of the first and second set of antennas for receiving the ranging signals based on the signal quality characteristics. 12. The navigation computer of claim 6 , wherein: the processor computes the variable separation baselines for both a first section of the auxiliary equipment and a second section of the auxiliary equipment that each move independently in relation to the vehicle; and the processor computes positions of the vehicle based on the variable separation baselines for the first section and second section of the auxiliary equipment.