Described herein are methods and systems for generating shared collaborative maps for planting or harvesting operations. A method of generating a collaborative shared map between machines includes generating a first map for a first machine based on a first set of data and generating a second map for a second machine based on a second set of data. The method further includes generating at least one shared collaborative map for at least one of the first and second machines based on the first and second maps.

A method and system are provided for determining a threshing loss in a threshing system. The method includes irradiating a crop sample downstream at least a portion of a threshing system with electromagnetic waves having a frequency in a range of 0.1-10 THz, measuring a reflection and/or a transmission of the electromagnetic waves by the crop sample, establishing, based on the measured reflection and/or transmission, an at least two-dimensional terahertz image of the crop sample, identifying at least one ear in the terahertz image, identifying at least one grain kernel in the identified ear, and determining the threshing loss based on the identified grain kernel.

A combine harvester is provided with a controller, and the controller functions as an automatic traveler and a switch. The automatic traveler executes the automatic traveling of the combine harvester in the automatic straight work. The switch switches automatic traveling of the combine harvester to manual traveling, during the performing of the automatic traveling, when detecting a shift from an un-mowed area to an already mowed area.

Control zones are dynamically identified on a thematic map and work machine actuator settings are dynamically identified for each control zone. A position of the work machine is sensed and actuators on the work machine are controlled based on the control zones that the work machine is in, and based upon the settings corresponding to the control zone. When modification criteria are met, an actuator setting in a control zone can be modified, during operation. The control zone is then divided on a near real-time display into a harvested portion of the control zone, and a new control zone that has yet to be harvested, and that has the modified actuator setting value. A record is then generated and stored, for the harvested control zone, and for the new control zone.

Control zones are dynamically identified on a thematic map and work machine actuator settings are dynamically identified for each control zone. A position of the work machine is sensed and actuators on the work machine are controlled based on the control zones that the work machine is in, and based upon the settings corresponding to the control zone. When modification criteria are met, an actuator setting in a control zone can be modified, during operation. The control zone is then divided on a near real-time display into a harvested portion of the control zone, and a new control zone that has yet to be harvested, and that has the modified actuator setting value. A record is then generated and stored, for the harvested control zone, and for the new control zone.

A system (1000) and method of marking soil or crops within afield with a visual strip (1001) to identify an occurrence of a detected event as an agricultural implement (10) traverses a field. The system includes an assembly (100, 200, 300, 500, 700, 800, 900) supported by the agricultural implement. The assembly includes a supply of a colored composition and an actuator (130, 330, 1030) configured to receive the actuation signals sent by the controller (80, 81). The actuator is responsive to the actuation signals to release the colored composition at the location on the field while the agricultural implement advances through the field in the forward direction of travel.

A system (1000) and method of marking soil or crops within afield with a visual strip (1001) to identify an occurrence of a detected event as an agricultural implement (10) traverses a field. The system includes an assembly (100, 200, 300, 500, 700, 800, 900) supported by the agricultural implement. The assembly includes a supply of a colored composition and an actuator (130, 330, 1030) configured to receive the actuation signals sent by the controller (80, 81). The actuator is responsive to the actuation signals to release the colored composition at the location on the field while the agricultural implement advances through the field in the forward direction of travel.

A control system for a working machine includes a ground engaging structure which performs a compaction operation by passing over a body of a harvested crop. The control system includes a controller and at least one sensor providing an input to the controller. The controller is configured to determine a state of compaction of a section of the body of the harvested crop based on at least the input from the sensor, and provides at least one output to control the movement of the working machine over the body of the harvested crop and also provides an indication to an operator of the working machine as to the state of compaction of the body of the harvested crop at a particular section thereof.

A control system for a working machine includes a ground engaging structure which performs a compaction operation by passing over a body of a harvested crop. The control system includes a controller and at least one sensor providing an input to the controller. The controller is configured to determine a state of compaction of a section of the body of the harvested crop based on at least the input from the sensor, and provides at least one output to control the movement of the working machine over the body of the harvested crop and also provides an indication to an operator of the working machine as to the state of compaction of the body of the harvested crop at a particular section thereof.

A combine includes a control device and a mobile terminal. The mobile terminal includes a control device, and when the control device detects movement to one field where automatic travel is to be performed, the control device functions as a parameter setting unit that sets a field parameter corresponding to the one field. The control device functions as a travel control unit that executes automatic travel of the combine on the basis of a work route set for the one field and the field parameter.