Crop feed rate control system for a harvester vehicle

What is claimed is: 1. A harvester vehicle comprising: a crop processing system comprising two or more crop processing components that operably process a harvested crop; a vehicle control system that operably controls a harvesting rate of the vehicle; and a crop feed rate control system that operably provides crop processing data to the vehicle control system, the crop feed rate control system comprising: one or more feedback systems that operably provide a feedback signal comprising data indicative of a detected load amount for the respective components of the crop processing system and indicative of a target load amount for one or more of the respective components of the crop processing system; a first control module that operably receives the feedback signal and generates a controlling load signal based at least upon the feedback signal, the controlling load signal being indicative of a controlling crop processing component of the two or more crop processing components of the crop processing system determined to have a limiting effect on the harvesting rate of the vehicle greater than limiting effects on the harvesting rate of the crop processing components other than the controlling crop processing component; and a second control module that operably receives a targeted load signal and the controlling load signal, the second control module operably generating the crop processing data indicative of a target harvesting rate for the vehicle that is different than the harvesting rate. 2. The harvester vehicle of claim 1 , the crop processing data used by the vehicle control system to control the harvesting rate by adjusting ground speed of the harvester. 3. The harvester vehicle of claim 2 , the first control module comprising a core system control module that determines the controlling crop processing component based at least upon the detected load amount and the target load as the crop processing component having a detected load to target load ratio greater than detected load to target load ratios of the crop processing components other than the controlling crop processing component. 4. The harvester vehicle of claim 1 , the crop feed rate control system comprising a fault monitor that sets the target load amount to zero when a speed sensor indicates a fault, resulting in a reduction of the harvesting rate. 5. The harvester vehicle of claim 1 , the second control module comprising a proportional integrative derivative (PID) and slew rate controller, the PID and slew rate controller using predetermined parameters to identify the target harvesting rate for the vehicle based at least on a difference between the controlling load and the target load for the controlling component, and determining a rate of change from the harvesting rate to the target harvesting rate of the vehicle based at least upon harvesting conditions. 6. The harvester vehicle of claim 5 , the second control module receiving one or more of the following, to be used by the PID and slew rate controller to identify the target harvesting rate and the rate of change from the harvesting rate to the target harvesting rate: an operably measured harvester vehicle speed; one or more predetermined PID parameters; one or more operator inputs; and one or more predetermined slew rate parameters. 7. The harvester vehicle of claim 1 , the two or more crop processing components comprising at least two of: a crop accumulator component that operably, temporarily stores the harvested crop, the crop accumulator component comprising an accumulator capacity monitor; a crop header component that operably harvests the crop from a target field, the crop header component comprising a header and a header system load monitor; a crop conveyor component that conveys the crop through the vehicle, the crop conveyor component comprising one or more air ducts and an air system load monitor; a crop cleaner component that operably cleans the harvested crop, the crop cleaner component comprising a cleaner system load monitor; a propulsion component that operably produces motion of the harvester vehicle, the propulsion component comprising at least one propulsion circuit, a propulsion device, and a propulsion system load monitor; and a map based farming (MBF) component that operably guides movement of the vehicle during harvesting, the MBF component comprising an MBF system monitor. 8. The harvester vehicle of claim 7 , wherein the accumulator capacity monitor operably receives an accumulator level signal indicative of a detected fill level in the accumulator and a mass flow rate signal indicative of a detected mass flow of the crop in the accumulator, and generates an accumulator feedback signal comprising data indicative of the targeted load amount for the accumulator component. 9. The harvester vehicle of claim 7 , further comprising a status monitoring component comprising a status monitor that operably receives a detected component load signal from respective components of the crop processing system and generates a feedback signal based at least on a load capacity of the respective components and the detected component load, the feedback signal comprising data indicative of the detected load amount for the respective components of the crop processing system. 10. The harvester vehicle of claim 9 , the status monitoring component updates a load capacity of the respective components of the crop processing system during operation, based at least on active calibration of an empty load condition. 11. The harvester vehicle of claim 7 , wherein the header system load monitor operably receives an in-operation header load signal indicative of a detected load at the header, and generates a load capacity feedback signal comprising data indicative of the detected load amount for the header component from one or more of: detected pressure at a header pressure pump; detected current through control valves of the pump in the header system; and a detected shaft rotation speed in the header. 12. The harvester vehicle of claim 7 , wherein the air system load monitor operably receives an air flow signal indicative of air flow in the one or more ducts, and generates a load capacity feedback signal comprising data indicative of the detected load amount for the air flow through the air ducts. 13. The harvester vehicle of claim 7 , wherein the cleaner system load monitor operably receives a detected cleaner load signal and generates a detected load amount feedback signal comprising data indicative of one or more of: a detected pressure at a pump in the cleaner system; a detected current through control valves of the pump in the cleaner system; and a detected shaft rotation speed. 14. The harvester vehicle of claim 7 , wherein the MBF system monitor operably receives a MBF signal indicative of a detected MBF load and generates a load capacity feedback signal comprising data indicative of a detected MBF load amount of capacity speed, based at least upon imaging that correlates a crop to a projected yield. 15. The harvester vehicle of claim 9 , wherein the status monitoring component further comprises an accumulator overfull monitor that operably receives a mass flow sensor response signal and generates a feedback signal comprising data indicative of a detected overfill condition in the accumulator of the crop processing system, resulting in the status monitor indicating a fault that reduces the harvesting rate. 16. A method for controlling feed rate in a harvester vehicle having a crop processing system comprising two or more crop processing components that operably pr