An implement adjusting system having an implement with a plurality of adjustable components, a plurality of input values, at least one controlled system configured to adjust at least one of the plurality of adjustable components, and a controller that receives the plurality of input values, the controller configured to reposition the plurality of adjustable components based on the plurality of input values. Wherein, the plurality of adjustable components are repositionable by the controller based on the input values.

An integrated computing system computes a geo-location of a vehicle based on location data generated by a GNSS receiver, operates one or more external communication interfaces, calculates a desired path for steering the vehicle based on the geo-location, and communicates the desired path to one or more external operating units via the one or more external communication interfaces. The integrated computing system may include one or more computer processing units programmed to provide shared coordinated execution of software functions that are all implemented and located within a same integrated circuit or enclosure. The integrated computing system lowers the overall cost and complexity of agricultural guidance systems by reducing and simplifying the number of chassis, boxes, connectors, power supplies, and manufacturing processes.

An information processing apparatus includes an interface configured to acquire route state information representing a state of a point through which at least one travel route of at least one work vehicle passes, and a controller configured to determine a travel route of the work vehicle based on the route state information and output the determined travel route to the work vehicle.

A system that includes an agricultural tractor that includes a steering mechanism for steering at least one surface-engaging member so as to cause changes in a direction of movement of the agricultural tractor; and an agricultural implement that is towed behind the agricultural tractor. The system further includes at least one forward sensor for sensing one or more objects or conditions located forwardly of the agricultural tractor and at least one lateral sensor for sensing one or more objects or conditions that when sensed are located laterally of the agricultural tractor or implement. The system further includes a controller that acts in dependence on at least one output of the at least one lateral sensor to take account of a presence of the one or more objects or conditions sensed by the at least one lateral sensor.

An agricultural work system has an agricultural work machine to which at least one mounted implement can be fitted via at least one implement interface. A work machine configuration is associated with the work machine, and a mounted implement configuration is associated with the mounted implement. A drive unit is provided which acts via a drivetrain on ground engaging elements, particularly on tires. A system control and a control/display unit associated with the work machine are provided. It is proposed that the system control is adapted to determine the mounted implement configuration, to calculate the implement interface load transmitted via the implement interface based on the determined mounted implement configuration, and to evaluate and/or optimize the work machine configuration based on the calculated implement interface load.

A method for detecting real lateral locations of target plants includes: recording an image of a ground area at a camera; detecting a target plant in the image; accessing a lateral pixel location of the target plant in the image; for each tool module in a set of tool modules arranged behind the camera and in contact with a plant bed: recording an extension distance of the tool module; and recording a lateral position of the tool module relative to the camera; estimating a depth profile of the plant bed proximal the target plant based on the extension distance and the lateral position of each tool module; estimating a lateral location of the target plant based on the lateral pixel location of the target plant and the depth profile of the plant bed surface proximal the target plant; and driving a tool module to a lateral position aligned with the lateral location of the target plant.

An agricultural vehicle (10) includes at least one geospatial sensor (44) for locating the vehicle (1) within a geographic area (14); at least one event trigger; at least one actuator for actuating a component onboard the vehicle (10); and a headland management system (HMS) (30) for carrying out a headland turn sequence (HTS) at a predetermined location within the geographic area (14). The HMS (30) includes a memory (34) for storing at least a portion of an HTS, and a visual display (46) for displaying at least a portion of an HTS. The vehicle (10) is characterized in that the HMS (30) is configured to display a real-time map on the visual display (46), including a position of the vehicle (10) on the map, and at least one future HTS event forming at least part of an HTS. The HMS (30) is configured to allow an operator to modify at least one HTS event on the real-time map.

The use of self-powered, autonomous vehicles in agricultural and other domestic applications is provided. The vehicles include a self-propelled drive system, tracks or wheels operatively connected to the drive system, a power supply operatively connected to the drive system, an attachment mechanism for attaching equipment to the vehicle, and an intelligent control operatively connected to the drive system, power supply, and attachment mechanism. The vehicle is configured to connect to the equipment to perform agricultural operations based upon the equipment. Multiple vehicles can be used in a field at the same time. Furthermore, the invention includes the ability to move one or more of the autonomous vehicles from field to field, home to field, or from generally any first location to a second location.

A modular autonomous agricultural vehicle includes a drive module having a frame, a ground-engaging element rotatably coupled to the frame, a power source, and a drive motor receiving power from the power source and coupled to the ground-engaging element for rotating the ground engaging element. At least one toolbar module is detachably coupled to the frame for coupling the drive module to an agricultural implement or another modular toolbar segment. The modular toolbar preferably includes multiple toolbar modules coupled to each other in series to form the modular toolbar.

In one aspect, a system for controlling the position of an agricultural implement being towed by an agricultural vehicle may include first and second wheels and first and second non-contact-based braking devices. As such, the first braking device may be configured to apply a braking force to the first wheel, and the second braking device may be configured to apply a braking force to the second wheel. Furthermore, the system may include a controller configured to control an operation of the first braking device or the second braking device when it is determined that the position of the implement differs from a predetermined position for the implement such that the braking force is applied to the corresponding wheel in a manner that adjusts the position of the implement towards the predetermined position.