An agricultural system includes a controller comprising a memory and a processor, wherein the controller is configured to receive data from a first and second sensor, each of which are mounted on an agricultural header and configured to output data indicative of one-dimensional (1D) distances. The controller is configured to determine a first horizontal distance from the first sensor to a first plant stalk and a second horizontal distance from the second sensor to a second plant stalk based on the 1D distance data. The controller is also configured to control a steering system of the agricultural system to adjust a position of the agricultural header relative to the first and second plant stalks based on a difference between the first horizontal distance and the second horizontal distance.

An agricultural vehicle includes a chassis (16), a lift arm (18) movably coupled to the chassis (16), a lift actuator (21) coupled to the lift arm (18), a header (14) coupled to the lift arm (18), and a controller (120) operably coupled to the lift actuator (21). The controller (120) is configured to: receive a header type signal corresponding to a header type of the header; define a lift height limit of the header based at least partially on the received header type signal, the lift height limit being a first height limit when a first header type signal is received or a second height limit when a second header type signal is received; and output a lift signal to the lift actuator (21) to vertically displace the header (14). Header vertical displacement is limited to the first height limit if the first header type signal is received or the second height limit if the second header type signal is received.

Method and apparatus for controlling the height of a header for use with an agricultural harvester. The header height is controlled by receiving orientation values from a first set of sensors representing orientation of respective support arms of the header, receiving height values from a second set of sensors representing height of the respective support arms with respect to ground, combining the height values and orientation values for each support arm to create a respective multi-sensor value, and controlling the position of the header with respect to the agricultural harvester responsive the multi-sensor value.

A system for controlling harvesting implement position of an agricultural harvester includes a harvesting implement configured to be coupled to the harvester to permit adjustment of a current position of the implement relative to a field surface. Additionally, the system includes a sensor configured to capture data indicative of the current position of the implement relative to the field surface, a display device, and a controller communicatively coupled to the sensor and the display device. As such, the controller is configured to monitor the current position of the implement based on the data captured by the sensor. Furthermore, the controller is further configured to initiate display of a graphical user interface on the display device, with the graphical user interface displaying a first interface element associated with the current position of the implement relative to a second interface element associated with a reference position of the implement.

In accordance with an example embodiment, an agricultural vehicle may include first and second harvesting devices connected to the agricultural vehicle. The agricultural vehicle may include a sensor which detects whether the agricultural vehicle is traveling in an operational or non-operational direction. The agricultural vehicle may include a lift controller in communication with the sensor and the first and second harvesting devices. The lift controller may automatically reposition the first and second harvesting devices into non-operating positions when the lift controller determines an intention to move the agricultural vehicle in a non-operational direction.

An agricultural harvester includes a chassis; at least one ground engaging traction member held by the chassis; a cutter held by the chassis; a sensor held by the agricultural harvester so that the sensor is directed in front of the cutter and configured to emit and receive sound and/or radio waves and produce a plurality of output signals; and an electrical processing circuit coupled to the sensor. The electrical processing circuit is configured to produce a field map from the plurality of output signals and adjust an operating parameter of the agricultural harvester based on the field map.

A control system for a header of an agricultural harvesting machine providing the capability for positioning the reel and the cutter bar, respectively, with a single input, the control system configured and co-operable with the input for recognizing multiple predetermined discrete patterns of operator input, and responsive thereto, positioning a reel and cutter bar at predetermined relative positions, respectively.

A harvesting head for an agricultural combine includes a frame and a support arm coupled to the frame. The support arm is configured to move between an unlocked state in which the support arm is moveable relative to the frame and a locked state in which the support arm is fixed relative to the frame. The harvesting head includes cutting teeth supported by the support arm relative to the frame. The cutting teeth are configured to move relative to the support arm in a reciprocating motion along a longitudinal axis of the frame. The harvesting head includes a gauge member coupled to the frame. The gauge member is configured to sense a height of the frame relative to a surface. The harvesting head includes a control assembly configured to move the support arm into the locked state based on the height of the frame relative to the surface.

A harvesting machine includes a chassis; an engine to propel the harvesting machine; a header mounted on a front of the chassis; a cutter bar arranged on the header to cut crops during operation of the harvesting machine; a plurality of implements on the chassis configured to facilitate processing the crops cut by the cutter bar; at least one cutter bar load sensor arranged on the header and configured to collect cutter bar load data representing a load on the cutter bar resulting from cutting the crops; and a controller operatively coupled to the at least one cutter bar sensor. The controller is configured to receive the cutter bar load data, determine a cutter bar load value based on the cutter bar load data, and generate an adjustment command for an operational parameter associated with at least one of the implements based on the cutter bar load value.

An agricultural vehicle includes a chassis (16), a lift arm (18) movably coupled to the chassis (16), a lift actuator (21) coupled to the lift arm (18), a header (14) coupled to the lift arm (18), and a controller (120) operably coupled to the lift actuator (21). The controller (120) is configured to: receive a header type signal corresponding to a header type of the header; define a lift height limit of the header based at least partially on the received header type signal, the lift height limit being a first height limit when a first header type signal is received or a second height limit when a second header type signal is received; and output a lift signal to the lift actuator (21) to vertically displace the header (14). Header vertical displacement is limited to the first height limit if the first header type signal is received or the second height limit if the second header type signal is received.