Abstract: A combine harvester which regulates spreading of crop flow on the ground, with the crop flow passing through a shredding and/or a spreading device in the rear region of the combine harvester, is disclosed. The combine harvester includes a driver assistance system, which includes a computing unit and a display unit. The computing unit processes information generated by the machine's internal sensor systems, external information and information storable in the computing unit. The driver assistance system stores selectable spreading strategies to regulate the spreading of the crop flow exiting the combine harvester and one or more of the partial strategies assigned to the respective spreading strategy. The driver assistance system uses the selectable spreading strategies and the partial strategies in order to regulate the crop flow spread on the ground.

Abstract: A self-propelled harvesting machine such as a combine harvester has multiple working units for processing crop picked up from a field, a driver assistance system for the sensor-supported control of the working units, an environmental sensor system for detecting environmental information and spatial areas of applicability located in the environment of the harvesting machine. The driver assistance system has a memory for storing data and a computing unit for processing data, including the data stored in the memory. A functional system model for at least one part of the harvesting machine is stored in the memory. The computing unit functions as a characteristic control on the basis of the system model and autonomously determines machine parameters of at least one working unit and specifies these to the particular working unit.

Abstract: An agricultural harvesting machine has a header designed as a front attachment for cutting and picking up crop and a driver assistance system for controlling the header. The driver assistance system has a memory for storing data and a computing unit for processing the data stored in the memory. The header together with the driver assistance system forms an automated header, in that a plurality of selectable harvesting-process strategies is stored in the memory and in order to implement a selected harvesting-process strategy or the selected harvesting-process strategies, the computing device autonomously determines at least one machine parameter, a header parameter and specifies this to the header.

Abstract: A combine harvester has a threshing unit for threshing picked-up crop to obtain grain, a driver assistance system for controlling the threshing unit which has a memory for storing data and a computing unit for processing the data stored in the memory. A functional system model for at least a portion of the combine harvester is stored in the memory. The computing unit is designed to carry out an autonomous determination of at least one threshing-unit parameter on a basis of the system model and, for depicting functional interrelationships, at least one family of characteristics (A-J) is assigned to at least one harvesting-process parameter. The at least one harvesting-process parameter is defined as an output variable of the at least one family of characteristics (A-J).

Abstract: A combine harvester has a threshing unit for threshing picked-up crop to obtain grain and a driver assistance system for controlling the threshing unit. The driver assistance system includes a memory for storing data and a computing unit for processing the data stored in the memory. The threshing unit, together with the driver assistance system, forms an automated threshing unit, in that a plurality of selectable harvesting-process strategies is stored in the memory and in that, in order to implement the particular selected harvesting-process strategy, the computing device autonomously determines at least one machine parameter, for example, a threshing-unit parameter, and specifies the parameter to the threshing unit.

Abstract: This disclosure relates to a method and device for the operation of a combine harvester with multiple work elements for harvesting a crop via a driver assistance system. In one example implementation, a method for operating such a combine harvester includes determining separately a harvest setting for the crop and a machine configuration of the combine harvester, preselecting a process control strategy among a plurality of process control strategies based on the harvest setting and machine configuration wherein each of the plurality of process control strategies is aimed at fulfillment of at least one harvesting quality criterion stored in the memory of the combine harvester, and automatically determining at least one machine parameter for the work elements of the combine harvester according to the preselected process control strategy and controlling the work elements corresponding to the at least one machine parameter.

Abstract: An agricultural work machine for processing an agricultural work process, having numerous working units (1-5) and having a driver assistance system (10) for controlling the working units (1-5) according to at least one user-side specifiable work process strategy (A), which is aimed at fulfilling at least one quality criterion (Q), wherein the driver assistance system (10) comprises a memory (11) for storing data, and a computing device (12) for processing the data stored in the memory (11), wherein the driver assistance system (10) has a graphical user interface (14), via which at least a portion of the work process strategy (A) can be specified by a user. It is proposed that competing quality criteria (Q) that are weighted in relation to one another in accordance with a weighting variable (G) are entered into the work process strategy (A), and that the weighting variable (G) is visualized and can be specified by a user via a virtual operating element (16-19) of the graphical user interface (14).

Abstract: An agricultural working machine has at least one working unit and a display device for displaying or adjusting parameters of the working machine the at least one working unit of both. The display device has a display unit with jointly depictable display elements for visualization of parameter-based values, the display elements preferably arranged concentrically in a form of circular-ring sections. The display device also includes at least one bar display that at least partially encircles the display elements radially on the outer side. Indicator element for displaying a defined value are disposed on the at least one bar display.

Abstract: An agricultural harvesting machine has a header designed as a front attachment for cutting and picking up crop and a driver assistance system for controlling the header. The driver assistance system has a memory for storing data and a computing unit for processing the data stored in the memory. The header together with the driver assistance system forms an automated header, in that a plurality of selectable harvesting-process strategies is stored in the memory and in order to implement a selected harvesting-process strategy or the selected harvesting-process strategies, the computing device autonomously determines at least one machine parameter, a header parameter and specifies this to the header.

Abstract: A combine harvester includes a driver assistance system that regulates a spreading on the ground of a crop flow exiting the combine harvester. The driver assistance system includes spreading strategies that can be selected in order to regulate the spreading of the crop flow exiting the combine harvester.

Abstract: A self-propelled harvesting machine such as a combine harvester has multiple working units for processing crop picked up from a field, a driver assistance system for the sensor-supported control of the working units, an environmental sensor system for detecting environmental information and spatial areas of applicability located in the environment of the harvesting machine. The driver assistance system has a memory for storing data and a computing unit for processing data, including the data stored in the memory. A functional system model for at least one part of the harvesting machine is stored in the memory. The computing unit functions as a characteristic control on the basis of the system model and autonomously determines machine parameters of at least one working unit and specifies these to the particular working unit.

Abstract: A combine harvester has a threshing unit for threshing picked-up crop to obtain grain and a driver assistance system for controlling the threshing unit. The driver assistance system includes a memory for storing data and a computing unit for processing the data stored in the memory. The threshing unit, together with the driver assistance system, forms an automated threshing unit, in that a plurality of selectable harvesting-process strategies is stored in the memory and in that, in order to implement the particular selected harvesting-process strategy, the computing device autonomously determines at least one machine parameter, for example, a threshing-unit parameter, and specifies the parameter to the threshing unit.

Abstract: A combine harvester includes a threshing unit for threshing picked-up crop to obtain grain, a driver assistance system, with a memory for storing data, for controlling the threshing unit, and a computing unit for processing at least the data stored in the memory. A sensor system ascertains at least a portion of the current harvesting-process state. A sensor configuration assigned to the sensor system is defined by the type and scope of operational sensors is stored or can be stored in the memory. A functional system model for at least a portion of the combine harvester is stored in the memory. The computing unit is designed to carry out an autonomous determination of a threshing-unit parameter based on the system model, and defines the system model forming a basis of the control of the threshing unit depending on the sensor configuration stored in the memory.

Abstract: A combine harvester has a threshing unit for threshing picked-up crop to obtain grain, a driver assistance system for controlling the threshing unit which has a memory for storing data and a computing unit for processing the data stored in the memory. A functional system model for at least a portion of the combine harvester is stored in the memory. The computing unit is designed to carry out an autonomous determination of at least one threshing-unit parameter on a basis of the system model and, for depicting functional interrelationships, at least one family of characteristics (A-J) is assigned to at least one harvesting-process parameter. The at least one harvesting-process parameter is defined as an output variable of the at least one family of characteristics (A-J).

Abstract: A method for determining calibration data for a grain-loss sensor on a combine harvester includes measuring grain-loss quantities, which were left behind by the combine harvester during a harvesting operation, and measuring sensor grain-loss values by the grain-loss sensor during the harvesting operation. Reference marks are assigned to the measured grain-loss quantities and the measured sensor grain-loss values and the calibration data for the grain-loss sensor are determined on the basis of a reconciliation of the measured grain-loss quantities with the measured sensor grain-loss values according to the reference marks.

Abstract: A combine harvester includes a driver assistance system that regulates a spreading on the ground of a crop flow exiting the combine harvester. The driver assistance system includes spreading strategies that can be selected in order to regulate the spreading of the crop flow exiting the combine harvester.

Abstract: A combine harvester has a spreading device for spreading chopped crop, a control device to which the spreading device is connected and which controls spreading properties of the spreading device, and a wind anemometer located on either side of the spreading device in a rear region of the combine harvester and producing a signal corresponding to a characteristic of wind.

Abstract: A method for automatic adjustment of at least one of several working units of a self-propelled harvesting machine involved in a harvesting process, includes the steps of initially modeling the harvesting process by at least one program map, based on a data base characteristic of a current harvesting process; determining an initial working point of the at least one of the working units on a basis of the initial modeling; adapting the at least one program map on a basis of data currently collected by measurements and which influence the harvesting process; determining a new working point of the at least one working unit depending on the adaptation of the program map; and iteratively approximating the new working point.

Abstract: A combine harvester operates with an axial separating device for separating a crop flow picked up by the combine harvester into a plurality of partial flows. A partial flow composed of grain and non-grain components is fed by a separation surface of the axial separating device to a cleaning unit disposed downstream. The axial separating device is configured to manipulate a local concentration gradient of the partial flow that is output by the axial separating device caused by a tilt of the combine harvester. The extent of the manipulation is controlled individually depending on the tilt of the combine harvester.

Abstract: An assistance system that optimizes the operation of a self-propelled agricultural working machine includes a device for determining working and efficiency parameters of the machine includes an arithmetic logic unit and a display unit. The arithmetic logic unit processes information generated by machine-internal sensor systems, external information and information stored in the arithmetic logic unit. One or more mathematical models describing the working process are stored in the arithmetic logic unit and derive efficiency parameters of the working machine from the available working parameters and, with consideration for monetary interrelationships, determine the opportunity costs of the working process and visualize the opportunity costs in the display unit.