Agricultural electronics include many components. The components can be connected via an electronic link that connects the various components to components of an agricultural implement. This can include the use of a component type identifier and a master module. The identifier and the module can communicate data, including identification data and instructional data, to easily acknowledge and operate various electrical components of the agricultural implement. Additional sensors can be included to provide even additional data that is communicated between the module and the components of the agricultural implement to aid in providing instructions for operation and to provide additional data information.

An agricultural facility arranged in a plot of farmland includes: a supply and/or maintenance station; an autonomous agricultural device performing an agricultural task in the plot of farmland; a control unit for moving the autonomous agricultural device and the station, which unit is configured to control movement of the autonomous agricultural device within the plot of farmland including a work area in which an agricultural task is performed by the autonomous agricultural device and an area to be worked in which an agricultural task is to be performed by the autonomous agricultural device. The control unit is configured to control movement of the station from the work area to the area to be worked if the autonomous agricultural device moves to perform an agricultural task in the area to be worked, movement of the station being independent from movement of the autonomous agricultural device.

Various embodiments relate generally to computer vision and automation to autonomously survey an agricultural environment. In some examples, a system can receive sensor data of a geographic boundary from one or more sensors onboard of the agricultural observation system, detect a plurality of external dynamic objects, a plurality of external static objects, one or more agricultural objects, or a combination thereof from the sensor data, determine a position of a component of the agricultural observation system relative to the plurality of external dynamic objects, the plurality of external static objects, the one or more agricultural objects, or a combination thereof, and generate a local map, in real time, via one or more processing units.

Aspects of present disclosure relate to an automated guided schedule agriculture spraying machine. The automated guided schedule agriculture spraying machine comprises of a plurality of navigation sensors for navigation of the machine; a plurality of vision sensors for path detection; a navigation module to determine location; a plurality of wheel differential drive units to drive the machine; a processor for controlling operation; and a sprayer module for spraying chemicals on plants. It is an automated guided schedule agriculture spraying machine having RTK-DGPS navigation system useful for performing precise and efficient spraying of chemicals. In addition to forward/rear travel, the machine is able to operate in traverse, sidling and spin-turn travel. Both travel and elevation are electrically operated and completely oil-free, avoiding oil spill contamination of the floor surface.

A cultivated land work vehicle includes a vehicle position computer, a travel controller to control travel of the body based on a vehicle position and target routes, and a replenishment mode executor to execute a replenishment travel mode to replenish the cultivated land work vehicle with agricultural material, during U-turn transition travel. In a first replenishment travel mode, reverse travel into the boundary area is performed after a starting point of the next travel route his reached, and forward travel to the starting point of the next travel route his performed after replenishment work is complete. In a second replenishment travel mode, reverse travel into the boundary area is performed before the starting point of the next travel route is reached, and forward travel to the starting point of the next travel route is performed after the replenishment work is complete.

A system for picking up, bundling and depositing agricultural material having a traction vehicle and a towed implement, the system comprising: an actuator associated with the implement; a control device configured to generate control data for controlling the orientation of the implement and steering of the traction vehicle, the control data including information relating to the orientation of the implement adjustable by the actuator, a desired orientation of the deposited agricultural material and at least one of a speed and a direction of travel of the traction vehicle; and wherein, using the control data, the actuator adjusts the orientation about a vertical axis of the implement relative to the traction vehicle to deposit the agricultural material.

A guidance system that automatically switches guidance modes in connection with executing an end turn. As the agricultural machine travels in a first, row sense guidance mode along a first guidance line in a non-coverage area, an approaching boundary between the non-coverage area and a headland area is identified. If the headland area contains crop rows, then, upon reaching the boundary, the guidance system switches to a second, GPS guidance mode. The agricultural machine travels along a first turn guidance line from the first guidance line to a preexisting headland guidance line, wherein the guidance system switches to the first guidance mode. The agricultural machine then travels in a direction parallel to the crop rows of the headland area. When leaving the headland guidance line, the guidance system switches to the second guidance mode, and then back to the first guidance mode upon the agricultural machine returning to the boundary.

A guidance system identifies a parking path and a target point in a parking area. The guidance system calculates steering commands to steer the vehicle and trailer onto the parking path. The guidance system calculates a distance of the trailer from the target point and calculates speed commands for the vehicle based on the distance of the trailer from the target point. The guidance system sends the steering and speed commands to a steering and speed control system to steer the vehicle and move the trailer along the parking path until the trailer reaches the target point in the parking area.

A method and apparatus for controlling an agricultural harvesting campaign is disclosed in which predetermined harvesting activities are processed within a campaign timeline by a plurality of agricultural working machines of a machine fleet on a field allotment assigned to the harvesting campaign. The control of the harvesting campaign is executed on different application levels by continuously generating information, wherein the generated information is continuously provided to all of the application levels, and the generated data comprise remotely-sensed field information.

An autonomous skid-steer machine includes a chassis, a plurality of ground engaging elements supporting the chassis on a ground surface and one or more computing devices for controlling movement of the machine. The one or more computing devices are configured to generate a control signal for controlling operation of at least some of the plurality of ground engaging elements, the control signal being generated according to a control algorithm incorporating tuning parameters, and to automatically determine the tuning parameters in real time during operation of the machine such that the control algorithm is always optimized for a current speed of the machine. The tuning parameters are found using the machine's current speed, a natural frequency value and a damping value.