Combine harvester with fan speed adjust

What is claimed is: 1. A combine harvester comprising: a chaffer to separate residue from grain in crop material; a fan to direct air across and through the chaffer to carry the residue from the harvester; a sensor to output signals indicating a characteristic of the crop material upstream of the chaffer; and a controller to adjust a speed of the fan based on signals from the sensor; and a second sensor downstream the chaffer, wherein the second sensor is to sense grain flow into a holding tank of the combine harvester and wherein the controller is to adjust the speed of the fan based upon a combination of signals from the sensor and the second sensor. 2. The combine harvester of claim 1 further comprising a rotor or threshing cylinder to engage and thresh the crop material prior to the crop material reaching the chaffer, wherein the signals output by the sensor indicate a throughput of the rotor or threshing cylinder, wherein the sensor comprises a sensor to sense forces exerted upon the rotor or threshing cylinder by the crop material. 3. The combine harvester of claim 1 further comprising a rotor or threshing cylinder to engage and thresh the crop material prior to the crop material reaching the chaffer, wherein the signals output by the sensor indicate a throughput of the rotor or threshing cylinder, wherein the signals output by the sensor indicating the throughput of the rotor are based upon power consumed to rotate the rotor or threshing cylinder. 4. The combine harvester of claim 1 further comprising a rotor or threshing cylinder to engage and thresh the crop material prior to the crop material reaching the chaffer, wherein the signals output by the sensor indicate a throughput of the rotor or threshing cylinder, wherein the signals output by sensor indicating the throughput of the rotor or threshing cylinder are based upon a rotational speed of the rotor or threshing cylinder. 5. The combine harvester of claim 1 further comprising a rotor or threshing cylinder to engage and thresh the crop material prior to the crop material reaching the chaffer, wherein the sensor comprises a capacitive sensor coated upon a portion of the rotor or threshing cylinder. 6. The combine harvester of claim 1 further comprising a rotor or threshing cylinder to engage and thresh the crop material prior to the crop material reaching the chaffer, wherein the sensor comprises an accelerometer mounted to the rotor or threshing cylinder. 7. The combine harvester of claim 1 further comprising a rotor or threshing cylinder to engage and thresh the crop material prior to the crop material reaching the chaffer, wherein the sensor comprises a pressure sensor carried by the rotor or threshing cylinder. 8. The combine harvester of claim 1 further comprising a rotor or threshing cylinder to engage and thresh the crop material prior to the crop material reaching the chaffer, wherein the sensor comprises an emitter-detector arrangement. 9. The combine harvester of claim 1 further comprising a third sensor to output third signals indicating a characteristic of the crop material upstream of the chaffer, wherein the controller is to differently weight the signals output by the sensor and the third signals and is to adjust the speed of the fan based on a combination of the differently weighted signals output by the sensor and the third signals. 10. The combine harvester claim 1 , wherein the controller is to apply first weight to the signals output by the sensor in response to a first harvesting condition and is to apply second weight, different than the first weight, to the signals output by the sensor in response to a second harvesting condition. 11. A combine harvester comprising: a chaffer to separate residue from grain in crop material; a fan to direct air across and through the chaffer to carry the residue from the harvester; a sensor to output signals indicating a characteristic of the crop material upstream of the chaffer; a controller to adjust a speed of the fan based on signals from the sensor; a ground speed sensor, wherein the controller is to adjust the fan speed based on a combination of signals from the sensor and the ground speed sensor; a second sensor to output signals indicating crop material downstream the chaffer, wherein the controller to adjust the fan speed based upon a combination of signals from the sensor, signals from the ground speed sensor and signals from the second sensor; and a rotor or threshing cylinder to engage and thresh the crop material prior to the crop material reaching the chaffer, wherein the signals output by the sensor indicate a throughput of the rotor or threshing cylinder. 12. The combine harvester of claim 11 , wherein the sensor comprises a pressure sensor to sense forces exerted upon the rotor or threshing cylinder by the crop material. 13. The combine harvester of claim 11 , wherein the signals output by the sensor indicating the throughput of the rotor or threshing cylinder are based upon power consumed to rotate the rotor or threshing cylinder. 14. The combine harvester of claim 11 , wherein the signals output by sensor indicating the throughput of the rotor or threshing cylinder are based upon a rotational speed of the rotor or threshing cylinder. 15. A combine harvester comprising: a chaffer to separate residue from grain in crop material; a fan to direct air across and through the chaffer to carry the residue from the harvester; a sensor to output signals indicating a characteristic of the crop material upstream of the chaffer a rotor or threshing cylinder to engage and thresh the crop material prior to the crop material reaching the chaffer; and a controller to adjust a speed of the fan based on signals from the sensor, wherein the signals output by the sensor indicate the throughput of the rotor or threshing cylinder based upon either the rotational speed of the rotor or threshing cylinder or the power consumed to rotate the rotor or threshing cylinder. 16. The combine harvester of claim 15 , wherein the signals output by the sensor indicating the throughput of the rotor or threshing cylinder are based upon the power consumed to rotate the rotor or threshing cylinder. 17. The combine harvester of claim 15 , wherein the signals output by sensor indicating the throughput of the rotor or threshing cylinder are based upon the rotational speed of the rotor or threshing cylinder. 18. The combine harvester of claim 15 further comprising a second sensor to output second signals indicating a characteristic of the crop material upstream of the chaffer, wherein the controller is to differently weight the signals output by the sensor and the second signals and is to adjust the speed of the fan based a combination of the differently weighted signals output by the sensor and the second signals. 19. The combine harvester claim 18 , wherein the controller is to apply first weight to the signals output by the sensor in response to a first harvesting condition and is to apply second weight, different than the first weight, to the signals output by the sensor in response to a second harvesting condition. 20. A combine harvester comprising: a chaffer to separate residue from grain in crop material; a fan to direct air across and through the chaffer to carry the residue from the harvester; a sensor to output signals indicating a characteristic of the crop material upstream of the chaffer, wherein the signals output by the sensor indicate the moisture content of the crop material; a rotor