A spreader tool for an agricultural machine, which includes an inlet into which material is passed from one or more further components of the agricultural machine and an outlet through which the material may be deposited from the machine. A sensing unit is positioned within the flow path of material deposited through the outlet and configured, in use, to measure an impact parameter indicative of a force and/or frequency of material deposited from the spreader tool and incident on a detection surface of the sensing unit, which may be used to determine the grain loss associated with the machine.

A header for a harvesting machine which includes one or more crop-engaging components and a sensing unit positioned within a flowpath of material and downstream of at least one of the one or more crop-engaging components. The sensing unit is configured, in use, to measure an impact parameter indicative of a force and/or frequency of material incident on a detection surface of the sensing unit in order to determine a measure of grain loss associated with the header.

A system for controlling harvesting implement height of an agricultural harvester may include a computing system configured to monitor the height of a harvesting implement of the harvester relative to a field surface based on the received sensor data. Additionally, the computing system may be configured to determine an implement height error signal by comparing the monitored height of the harvesting implement to a predetermined target height. Moreover, the computing system is configured to divide the determined implement height error signal into a first and second frequency portions, with the second frequency portion having a greater frequency than the first frequency portion. Furthermore, the computing system is configured to control the operation of first and second actuators of the harvester based on the first and second frequency portions of the implement height error signal, respectively.

Implementations relate to detecting/replacing transient obstructions from high-elevation digital images, and/or to fusing data from high-elevation digital images having different spatial, temporal, and/or spectral resolutions. In various implementations, first and second temporal sequences of high-elevation digital images capturing a geographic area may be obtained. These temporal sequences may have different spatial, temporal, and/or spectral resolutions (or frequencies). A mapping may be generated of the pixels of the high-elevation digital images of the second temporal sequence to respective sub-pixels of the first temporal sequence. A point in time at which a synthetic high-elevation digital image of the geographic area may be selected. The synthetic high-elevation digital image may be generated for the point in time based on the mapping and other data described herein.

Implementations relate to detecting/replacing transient obstructions from high-elevation digital images, and/or to fusing data from high-elevation digital images having different spatial, temporal, and/or spectral resolutions. In various implementations, first and second temporal sequences of high-elevation digital images capturing a geographic area may be obtained. These temporal sequences may have different spatial, temporal, and/or spectral resolutions (or frequencies). A mapping may be generated of the pixels of the high-elevation digital images of the second temporal sequence to respective sub-pixels of the first temporal sequence. A point in time at which a synthetic high-elevation digital image of the geographic area may be selected. The synthetic high-elevation digital image may be generated for the point in time based on the mapping and other data described herein.

A driver assistance system of an agricultural harvesting machine with a harvesting header designed as a draper is disclosed. The driver assistance system comprises a memory for storing data and a computing device for processing the data saved in the memory. The draper comprises a central belt and at least one transverse conveyor belt arranged on the left side and the right side of the central belt for conveying the harvested material to the central belt. The draper forms, together with the driver assistance system, an automatic draper. The computing device operates the automatic draper as a characteristic diagram controller using the saved characteristic diagrams, with the automatic draper optimizing operating parameters of the draper and specifying the optimized operating parameters for the draper. The characteristic diagrams describe the relationship between the operating parameters and quality parameters, and a control characteristic curve is assigned to the particular characteristic diagram.

A driver assistance system of an agricultural harvesting machine with a harvesting header designed as a draper is disclosed. The driver assistance system comprises a memory for storing data and a computing device for processing the data saved in the memory. The draper comprises a central belt and at least one transverse conveyor belt arranged on the left side and the right side of the central belt for conveying the harvested material to the central belt. The draper forms, together with the driver assistance system, an automatic draper. The computing device operates the automatic draper as a characteristic diagram controller using the saved characteristic diagrams, with the automatic draper optimizing operating parameters of the draper and specifying the optimized operating parameters for the draper. The characteristic diagrams describe the relationship between the operating parameters and quality parameters, and a control characteristic curve is assigned to the particular characteristic diagram.

A driver assistance system of an agricultural harvesting machine with a harvesting header designed as a draper is disclosed. The driver assistance system comprises a memory for storing data and a computing device for processing the data saved in the memory. The draper comprises a central belt and at least one transverse conveyor belt arranged on the left side and the right side of the central belt for conveying the harvested material to the central belt. The draper forms, together with the driver assistance system, an automatic draper. The computing device operates the automatic draper as a characteristic diagram controller using the saved characteristic diagrams, with the automatic draper optimizing operating parameters of the draper and specifying the optimized operating parameters for the draper. The characteristic diagrams describe the relationship between the operating parameters and quality parameters, and a control characteristic curve is assigned to the particular characteristic diagram.

An agricultural production machine comprising a characteristic diagram control is disclosed. The characteristic diagram control comprises one or more characteristic diagrams. Each characteristic diagram is configured to optimize operating parameters of the process units of the agricultural production machine. The particular characteristic diagram is designed as an initial characteristic diagram. In the initial characteristic diagram, at least the relationship between operating parameters of a process unit and quality parameters is described by initial operating points. A control characteristic curve is associated with the particular characteristic diagram, and the control characteristic curve lies around the minimum or maximum of the particular quality parameter.

An agricultural production machine comprising a characteristic diagram control is disclosed. The characteristic diagram control comprises one or more characteristic diagrams. Each characteristic diagram is configured to optimize operating parameters of the process units of the agricultural production machine. The particular characteristic diagram is designed as an initial characteristic diagram. In the initial characteristic diagram, at least the relationship between operating parameters of a process unit and quality parameters is described by initial operating points. A control characteristic curve is associated with the particular characteristic diagram, and the control characteristic curve lies around the minimum or maximum of the particular quality parameter.