The disclosed apparatus, systems, and methods relate to an automated hitch and various alternative devices to adjust the orientation of an agricultural implement and component parts thereof, including but not limited to a planter toolbar and/or planter row units relative to the soil surface to ensure the implement/components parts thereof maintain a position parallel to the soil surface.

The disclosed apparatus, systems, and methods relate to an automated hitch and various alternative devices to adjust the orientation of an agricultural implement and component parts thereof, including but not limited to a planter toolbar and/or planter row units relative to the soil surface to ensure the implement/components parts thereof maintain a position parallel to the soil surface.

In one aspect, a system for monitoring the frame levelness of an agricultural implement may include an implement frame and first and second seedbed detection assemblies coupled to the implement frame. Each of the seedbed detection assemblies may include a seedbed tool configured to ride along a seedbed floor as the implement frame is moved across a field in a forward travel direction. Each of the seedbed detection assemblies may also include a seedbed floor sensor configured to capture data indicative of a position of the corresponding seedbed tool relative to the implement frame. Furthermore, the system may include a controller configured to monitor positions of the seedbed detection assemblies relative to the implement frame based on data received from the seedbed floor sensors of the first and second seedbed detection assemblies, respectively.

In one aspect, a system for monitoring the frame levelness of an agricultural implement may include an implement frame and first and second seedbed detection assemblies coupled to the implement frame. Each of the seedbed detection assemblies may include a seedbed tool configured to ride along a seedbed floor as the implement frame is moved across a field in a forward travel direction. Each of the seedbed detection assemblies may also include a seedbed floor sensor configured to capture data indicative of a position of the corresponding seedbed tool relative to the implement frame. Furthermore, the system may include a controller configured to monitor positions of the seedbed detection assemblies relative to the implement frame based on data received from the seedbed floor sensors of the first and second seedbed detection assemblies, respectively.

Systems, methods, and apparatus for shifting weight between a tractor and toolbar and between sections of the toolbar and for folding a toolbar between a field position and a transport position.

A system for assessing agricultural operation performance may include an imaging device configured to capture image data associated with a portion of a field present within a field of view. The field of view may, in turn, include a first section directed at one of a processed or an unprocessed portion of the field and a second section directed at the other of the processed or the unprocessed portion of the field. Furthermore, a controller may be configured to determine a first value of a field characteristic for the processed portion of the field based on a first portion of the image data associated with the processed portion of the field. Additionally, the controller may be configured to determine a second value of a field characteristic for the unprocessed portion of the field based on a second portion of the image data associated with the unprocessed portion of the field.

A system for assessing agricultural operation performance may include an imaging device configured to capture image data associated with a portion of a field present within a field of view. The field of view may, in turn, include a first section directed at one of a processed or an unprocessed portion of the field and a second section directed at the other of the processed or the unprocessed portion of the field. Furthermore, a controller may be configured to determine a first value of a field characteristic for the processed portion of the field based on a first portion of the image data associated with the processed portion of the field. Additionally, the controller may be configured to determine a second value of a field characteristic for the unprocessed portion of the field based on a second portion of the image data associated with the unprocessed portion of the field.

A method for controlling the speed of a work vehicle towing an implement that is movable between a working position, in which ground engaging tools of the implement are configured to perform a field operation, and a transport position, in which the ground engaging tools are raised relative to the ground. The method may include monitoring, with a computing device, an implement weight supported by the implement while the implement is in the transport position. The method may further include comparing, with the computing device, the implement weight to a predetermined threshold weight. Additionally, the method may include, when the implement weight differs from the predetermined threshold weight, adjusting, with the computing device, a maximum speed limit for the work vehicle.

An auxiliary tool assembly for an agricultural implement is configured to support a finishing tool(s) at a location at or adjacent to the aft end of the implement. The auxiliary tool assembly includes a support arm extending lengthwise between a proximal end and a distal end, with the proximal end of the support arm being pivotally coupled to a portion of the implement at or adjacent to its aft end so that the tool assembly is pivotable relative to the implement between a work position and a transport position. In addition, the finishing tool(s) is configured to be coupled to or otherwise supported relative to the ground by the support arm at a location between its proximal and distal ends. Moreover, the auxiliary tool assembly includes one or more surface-engaging wheels coupled to the distal end of the support arm.

In one aspect, a system for controlling the direction of travel of agricultural implements may include a work vehicle having a vehicle-based controller configured to control an operation of a valve provided in operative association with the work vehicle. The system may also include an agricultural implement configured to be towed by the work vehicle. The implement may include a sensor configured to detect an operational parameter indicative of a direction of travel of the implement. The implement may also include an actuator configured to adjust the direction of travel of the implement, with the actuator being fluidly coupled to the valve such that the valve is configured to control an operation of the actuator. The implement may further include an implement-based controller configured to initiate control of the operation of the valve based on sensor data received from the sensor to adjust the direction of travel of the implement.