Air seeding turn compensation using yaw rate from sensor on towing vehicle

What is claimed is: 1. An agricultural system, comprising: a towing vehicle; an agricultural machine, coupled to the towing vehicle, including an application tool that applies material to a field at work points distributed along a transverse axis of the application tool; an instantaneous yaw rate detector detecting an instantaneous yaw rate of the towing vehicle; a tool yaw rate prediction system predicting, based on the instantaneous yaw rate detected on the towing vehicle, a plurality of different yaw rate values, each predicted yaw rate value of the plurality of different predicted yaw rate values corresponding to a respective work point of a set of the work points distributed along the transverse axis of the application tool; and a meter controller configured to control a meter that controls a rate at which the material is provided to the work points based on the plurality of different predicted yaw rate values, wherein the meter controller comprises a curve/table accessing system configured to access a pre-defined correlation that correlates predicted yaw rate values to control signal values to obtain a control signal for the meter controller. 2. The agricultural system of claim 1 wherein the agricultural machine comprises: an air cart that provides the material to the application tool through the meter. 3. The agricultural system of claim 1 and further comprising: a yaw rate aggregator aggregating a plurality of detected instantaneous yaw rates to obtain a set of aggregated instantaneous yaw rates. 4. The agricultural system of claim 3 wherein the tool yaw rate prediction system is configured to predict, based on the set of aggregated instantaneous yaw rates, the plurality of different predicted yaw rate values. 5. The agricultural system of claim 1 wherein the tool yaw rate prediction system comprises: a curve/table accessing system configured to access a pre-defined correlation that correlates instantaneous yaw rate values to predicted yaw rate values to obtain the plurality of different predicted yaw rate values. 6. The agricultural system of claim 1 wherein the tool yaw rate prediction system comprises: a runtime calculation system configured to perform a run time calculation based on the instantaneous yaw rate to obtain the plurality of different predicted yaw rate values. 7. The agricultural system of claim 1 wherein the meter controller further comprises: a runtime calculation system configured to perform a run time calculation based on the plurality of different predicted yaw rate values to obtain the control signal for the meter controller. 8. The agricultural system of claim 1 wherein the instantaneous yaw rate detector comprises: a wheel angle detector configured to detect a wheel angle of a wheel on the towing vehicle. 9. The agricultural system of claim 1 wherein the instantaneous yaw rate detector comprises: a steering wheel angle detector configured to detect a steering wheel angle of a steering wheel on the towing vehicle. 10. A computer-implemented method of controlling an agricultural machine, comprising: detecting, on a towing vehicle, an instantaneous yaw rate of the towing vehicle, the towing vehicle towing an application tool that applies material to a field at work points distributed along a transverse axis of the application tool; predicting, based on the instantaneous yaw rate detected on the towing vehicle, a plurality of different yaw rate values, each predicted yaw rate value of the plurality of different predicted yaw rate values corresponding to a respective work point of a set of the work points distributed along the transverse axis of the application tool; and controlling a meter that controls a rate at which the material is provided to the work points based on the plurality of different predicted yaw rate values, wherein controlling the meter comprises accessing a pre-defined correlation that correlates predicted yaw rate values to control signal values to obtain a control signal for controlling the meter. 11. The computer-implemented method of claim 10 and further comprising: aggregating a plurality of detected instantaneous yaw rates to obtain a set of aggregated instantaneous yaw rates. 12. The computer-implemented method of claim 11 wherein predicting comprises: predicting, based on the aggregated instantaneous yaw rates, the plurality of different predicted yaw rate values. 13. The computer-implemented method of claim 10 wherein predicting comprises: accessing a pre-defined correlation that correlates instantaneous yaw rate values to predicted yaw rate values to obtain the plurality of different predicted yaw rate values. 14. The computer-implemented method of claim 10 wherein predicting comprises: performing a run time calculation based on the instantaneous yaw rate to obtain the plurality of different predicted yaw rate values. 15. The computer-implemented method of claim 10 and further comprising: performing a run time calculation based on the predicted yaw rate values; and further controlling the meter based on the run time calculation. 16. The computer-implemented method of claim 10 wherein detecting an instantaneous yaw rate of the towing vehicle comprises: detecting a wheel angle of a wheel on the towing vehicle. 17. The computer-implemented method of claim 10 wherein detecting an instantaneous yaw rate of the towing vehicle comprises: detecting a steering wheel angle of a steering wheel on the towing vehicle. 18. An agricultural system, comprising: a towing vehicle; an agricultural machine, coupled to the towing vehicle, including an application tool that applies material to a field at work points distributed along a transverse axis of the application tool; an instantaneous yaw rate detector detecting an instantaneous yaw rate of the towing vehicle; a tool yaw rate prediction system predicting, based on the instantaneous yaw rate detected on the towing vehicle, a plurality of different yaw rate values, each predicted yaw rate value of the plurality of different predicted yaw rate values corresponding to a respective work point of a set of the work points distributed along the transverse axis of the application tool, wherein the tool yaw rate prediction system is configured to access a pre-defined correlation that correlates instantaneous yaw rate values to predicted yaw rate values to obtain the plurality of different predicted yaw rate values; and a meter controller configured to control a meter that controls a rate at which the material is provided to the work points based on the plurality of different predicted yaw rate values. 19. A computer-implemented method of controlling an agricultural machine, comprising: detecting, on a towing vehicle, an instantaneous yaw rate of the towing vehicle, the towing vehicle towing an application tool that applies material to a field at work points distributed along a transverse axis of the application tool; predicting, based on the instantaneous yaw rate detected on the towing vehicle, a plurality of different yaw rate values, each predicted yaw rate value of the plurality of different predicted yaw rate values corresponding to a respective work point of a set of the work points distributed along the transverse axis of the application tool, wherein predicting comprises accessing a pre-defined correlation that correlates instantaneous yaw rate values to predicted yaw rate values to obtain the plurality of different predicted yaw rate values; and controlling a meter that controls a rate