A steering system for controlling an agricultural machine having a pair of front and rear wheels includes a controller and a steer input sensor for detecting a change in an operator steer input corresponding to a steer command. The system includes a displacement input for communicating a motor displacement associated with an operating mode. A primary differential steering system includes a drive motor for operably controlling the pair of front wheels and a secondary steering system controls the pair of rear wheels. The controller determines if the motor displacement is being controlled according to a first motor displacement or a second motor displacement, and outputs a control signal to actuate first and second actuators as a function of the steer command. The control signal includes a rear steering gain that is a function of machine speed and either the first motor displacement or the second motor displacement.

Provided is a method of automatically combining a farm vehicle with a work machine including confirming a current position of the work machine, moving a farm vehicle into a range having a predetermined radius around the current position, and controlling the farm vehicle, on the basis of a current position and direction of a first coupling unit included in the work machine, so that the first coupling unit and a second coupling unit included in the farm vehicle are coupled to each other.

A steering system for an agricultural machine includes a first and second wheel assembly. Each wheel assembly includes an axle assembly including an axle, wheels rotatably connected to the axle, and a double-action hydraulic cylinder. In some embodiments, the double-action hydraulic cylinder is configured to pivot the wheels in either direction to indicate a direction of turn. In some embodiments, the double-action hydraulic cylinder of the first wheel assembly is hydraulically linked in its operation to an operation of the double-action hydraulic cylinder of the second wheel assembly.

A steering system for controlling an agricultural machine having a pair of front wheels and a pair of rear wheels includes a controller, an operator steer input for communicating a steer command, a steer input sensor for detecting and outputting the steer command to the controller, a primary differential steering system for operably controlling the pair of front wheels, and a secondary steering system for operably controlling the pair of rear wheels. The secondary steering system includes a first actuator for controlling a first rear wheel and a second actuator for controlling a second rear wheel. The primary differential steering system is controlled based on the steer command. The controller outputs a control signal to operably actuate the first and second actuators at a non-linear steering gain rate as a function of the steer command.

A support system for determining a trajectory to be followed by an agricultural work vehicle when working a field comprises: a mapping unit configured for receiving: i) coordinates relating to the boundaries of a field to be worked; and ii) coordinates relating to the boundaries of one or more obstacles to be avoided the work vehicle; wherein the one or more obstacles being located within the field; a capacity parameter unit configured for receiving one or more capacity parameters relating to the working vehicle; a trajectory calculating unit configured for calculating an optimized trajectory to be followed by the work vehicle; wherein the optimized trajectory is being calculated on the basis of the coordinates received by the mapping unit; and one or more of the one or more capacity parameters received by the capacity parameter unit.

An agricultural system includes a controller having a memory and a processor. The controller is configured to determine a steering angle of a work vehicle of the agricultural system, determine a target height of a ground engaging tool of the agricultural system based on the steering angle, and output a signal to control a height of the ground engaging tool relative to a soil surface based on the target height.

Steered caster wheel systems that include a disengagement system to enable a caster wheel steering mode and non-caster wheel steering mode are disclosed. In some embodiments, the caster wheels are mounted to a subframe that may be independently suspended from the chassis of a vehicle such as a self-propelled vehicle.

Methods, apparatus, systems and articles of manufacture are disclosed for field operations based on historical field operation data. An example apparatus disclosed herein includes a guidance line generator to generate a guidance line for operation of a vehicle during a second operation on a field, the guidance line based on (1) a field map generated from location data collected during a first operation in the field, the field map including a plurality of crop rows and (2) an implement of the vehicle, the implement to perform the second operation on the field. The example apparatus further includes a drive commander to cause the vehicle to traverse the field along the guidance line, and an implement commander to cause the implement to perform the second operation as the vehicle traverses the field along the guidance line.

A computer-implemented method for estimating a product consumption of an agricultural product for an agricultural field, comprising the steps: providing a target application rate map (10) comprising an application rate distribution of the agricultural product of the agricultural field, wherein the application rate distribution comprises different target areas with predetermined 5 application rates of the agricultural product (S100); providing a route (34, 52) of an agricultural vehicle and/or an application device of the agricultural vehicle through the agricultural field for applying the agricultural product (S200); providing a working width (37, 52) of the agricultural vehicle and/or the application device of the agricultural vehicle; determining application rates of the agricultural vehicle and/or the application device of the agricultural vehicle at least based on 10 the route (34, 52) of the agricultural vehicle and/or the application device of the agricultural vehicle through the agricultural field (S300); determining the product consumption for the agricultural field based on the determined application rates and the working width (37, 53) of the agricultural vehicle and/or the application device of the agricultural vehicle (S400). 15

Provided is a method of automatically combining a farm vehicle with a work machine including confirming a current position of the work machine, moving a farm vehicle into a range having a predetermined radius around the current position, and controlling the farm vehicle, on the basis of a current position and direction of a first coupling unit included in the work machine, so that the first coupling unit and a second coupling unit included in the farm vehicle are coupled to each other.