Threshing control system

What is claimed is: 1 . A method for controlling an agricultural harvester having a threshing system including a threshing concave that at least partially surrounds either a threshing rotor or a threshing drum, the method comprising: operating the threshing system so that crop material received from a feeder housing of the agricultural harvester is threshed causing smaller elements of the crop material to be discharged through perforations in the threshing concave while larger elements of the crop material are transferred by the threshing rotor or threshing drum towards a rear end of the agricultural harvester, using a camera that faces a rear end of the threshing rotor or threshing drum to obtain images of a crop flow at that location, processing the obtained images to detect grain ears therein, and deriving therefrom at least one physical property of the detected grain ears, and controlling an operational setting of the threshing system based on the derived at least one physical property, wherein the controlled operational setting is a concave clearance between an outer radius of the threshing rotor or threshing drum and an inner surface of the threshing concave, a concave opening of the threshing concave, and a rotational speed of the threshing rotor or threshing drum. 2 . The method as claimed in claim 1 , wherein the derived physical property is a threshed or partially unthreshed or unthreshed status of the detected grain ears. 3 . The method as claimed in claim 2 , whereby the status of the detected grain ear is determined as threshed, partially unthreshed or unthreshed if a ratio of the surface still covered with grain kernels over a total surface in the obtained image of the detected grain ear is smaller than 10%, between 10 and 90%, or greater than 90%, respectively. 4 . The method as claimed in claim 2 , wherein the operational setting of the threshing system is controlled of based on a determined percentage of unthreshed and/or partially threshed grain ears. 5 . The method as claimed in claim 1 , wherein the derived physical property is a dimensional characteristic of the detected grain ears. 6 . The method as claimed in claim 5 , wherein the operational setting of the threshing system is controlled based on a distribution of the dimensional characteristic of the detected grain ears. 7 . The method as claimed in claim 1 , wherein the derived physical property is a color of the detected grain ears. 8 . The method as claimed in claim 1 , wherein the controlled operational setting further includes a configuration of a rotor vane in a rotor cage above the threshing rotor or threshing drum. 9 . The method as claimed in claim 1 , wherein the derived physical property is a dimensional characteristic of the detected grain ears including a shape, length and/or width of the detected grain ears. 10 . The method as claimed in claim 1 , wherein the at least one derived physical property comprises a plurality of derived physical properties including: a threshed or partially unthreshed or unthreshed status of the detected grain ears, a dimensional characteristic of the detected grain ears, and a color of the detected grain ears, and wherein the operational setting of the threshing system is controlled based on the plurality of derived physical properties. 11 . An agricultural harvester comprising: a threshing system including at least one threshing rotor or threshing drum, cooperatively arranged in parallel to an opposing threshing concave, wherein the threshing rotor or the threshing drum in combination with the opposing threshing concave together configured to thresh crop material received from a feeder housing of the agricultural harvester causing smaller elements of the crop material to be discharged through perforations in the threshing concave while larger elements of the crop material are transferred by the threshing rotor towards a chopper for chopping the larger elements into smaller pieces, a camera positioned at a location that faces a rear end of the threshing rotor or the threshing drum for obtaining images of a crop flow at that location, a controller operatively coupled to the camera and configured that: receives the obtained images from the camera, processes the images to detect grain ears therein, and derives therefrom at least one physical property of the detected grain ears, and controls an operational setting of the threshing system based on the derived at least one physical property, wherein the controlled operational setting is a concave clearance between an outer radius of the threshing rotor or threshing drum and an inner surface of the threshing concave, a concave opening of the threshing concave, and a rotational speed of the threshing rotor or threshing drum. 12 . The agricultural harvester as claimed in claim 11 , further comprising a mechanical actuator operatively coupled to the controller and adjusts the concave clearance. 13 . The agricultural harvester as claimed in claim 11 , further comprising a speed adjustor operatively coupled to the controller and adjusts the rotational speed of the threshing rotor or threshing drum. 14 . The agricultural harvester as claimed in claim 11 , wherein the at least one physical property of the detected grain ears is a dimensional characteristic or color of the detected grain ears. 15 . An agricultural harvester comprising: a threshing system including at least one threshing rotor or threshing drum, cooperatively arranged in parallel to an opposing threshing concave, wherein the threshing rotor or the threshing drum in combination with the opposing threshing concave together thresh crop material received from a feeder housing causing smaller elements of the crop material to be discharged through perforations in the threshing concave while larger elements of the crop material are transferred by the threshing rotor towards a rear end of the agricultural harvester, a residue chopper positioned at the rear end, wherein in a chopper mode of the agricultural harvester the larger elements of the crop material are delivered to the chopper for chopping the larger elements of the crop material into smaller pieces, and wherein in a thresher mode of the agricultural harvester the larger elements of the crop material are guided along a bypass route that bypasses the residue chopper; a camera assembly for obtaining images of a crop flow at a first location residing at an outlet of the chopper and a second location residing along said bypass route, a controller operatively coupled to the camera assembly that: receives the obtained images from the camera assembly, processes the images to detect grain ears therein, and derives therefrom at least one physical property of the detected grain ears, and controls an operational setting of the threshing system based on the derived at least one physical property. 16 . The agricultural harvester as claimed in claim 15 , wherein the camera assembly is movably mounted such that it is movable between a first position to obtain images of the crop flow at the first location residing at the outlet of the chopper and a second position to obtain images of the crop flow at the second location residing along said bypass route. 17 . The agricultural harvester as claimed in claim 16 , further comprising a camera actuator that moves the camera assembly between the first and second positions. 18 . The agricultural harvester as claimed in claim 15 , wherein the camera assembly comprises a chopper camera and a thresher camera that are comb