Abstract: A system for monitoring the levelness of an agricultural implement may include first and second tools rotatably supported on the agricultural implement, with the first and second tools being spaced apart from each other in at least one of a longitudinal direction or a lateral direction of the agricultural implement. The system may further include a first rotational speed sensor configured to detect a rotational speed of the first tool and a second rotational speed sensor configured to detect a rotational speed of the second tool. Additionally, the system may include a controller communicatively coupled to the first and second rotational speed sensors, with the controller being configured to identify a levelness state of at least a portion of the agricultural implement based at least in part on the rotational speeds of the first and second tools.

Abstract: A system for managing material accumulation relative to ground engaging tools of an agricultural implement may include a ground engaging tool and an acoustic sensor configured to generate data indicative of an acoustic parameter of a sound produced as the ground engaging tool engages the ground when a ground engaging operation is performed within a field. Additionally, the system may include a controller communicatively coupled to the acoustic sensor. The controller may be configured to monitor the data received from the acoustic sensor and determine a presence of material accumulation relative to the ground engaging tool based at least in part on the acoustic parameter.

Abstract: A system for detecting plugging of ground-engaging tools of agricultural implements includes an aft sensor(s) configured to capture data indicative of a post-worked residue coverage of a portion of a field aft of a ground-engaging tool(s). The system includes a controller configured to monitor the data received from the aft sensor(s) and determine the post-worked residue coverage for the portion of the field. The controller is configured to identify when the ground-engaging tool(s) is experiencing a plugged condition based at least in part on the determined post-worked residue coverage for the field.

Abstract: In one aspect, a method for pre-emptively adjusting machine parameters based on predicted field conditions may include monitoring an operating parameter of as the agricultural machine makes a first pass across a field. The method may also include initiating active adjustments of the travel speed of the machine based on the operating parameter as the machine makes the first pass. Furthermore, the method may include generating a map based on the travel speed and the operating parameter that included efficiency zones associated with one or more travel speeds. Moreover, the method may include determining predicted efficiency zones for an adjacent second swath within the field based on efficiency zones of the first swath within the field map. Additionally, the method may include pre-emptively initiating adjustments of the travel speed as the machine makes a second pass across the field based on the efficiency parameter for each predicted efficiency zone.

Abstract: A system for detecting the operational status of ground engaging tools for agricultural implements includes an agricultural implement including a frame and a ground engaging tool coupled to the frame. The system further includes one or more sensors supported relative to the frame. The sensor(s) are configured to capture data indicative of a fluid flow past the ground engaging tool as the agricultural implement is moved across the field. The system further includes a controller configured to monitor the data received from the sensor(s) and identify an operational status of the ground engaging tool based at least in part on a comparison between one or more monitored values associated with the fluid flow past the ground engaging tool as the agricultural implement is moved across the field and a predetermined threshold value.

Abstract: In one aspect, a system for monitoring field profiles may include a vision-based sensor configured to capture vision data indicative of a profile of a field, with the profile being at least of a crop canopy profile of the field or a soil surface profile of the field. The system may also include a secondary sensor configured to capture secondary data indicative of the profile of the field. Furthermore, a controller of the disclosed system may be configured to receive the vision data from the vision-based sensor and the secondary data from the secondary sensor. Moreover, the controller may be configured to determine a quality parameter associated with the vision data. Additionally, when the quality parameter falls below a minimum threshold, the controller may be configured to determine at least a portion of the profile of the field based on the secondary data.

Abstract: 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.

Abstract: A system for determining the cut quality of a crop by a harvester includes an electrode maintained at voltage above ground. The electrode is mounted downstream of a cutter bar on the harvester. The electrode communicates with a controller which measures changes in an electrical parameter, such as voltage or current, between the electrode and ground. The electrode is positioned to ride at a particular height above the ground specific to a particular crop. Crop stubble left by crop which is cut cleanly by the harvester does not contact the electrode. Crop stubble left by crop which is not cut properly will engage the electrode and effect a change in the electrical parameter measured by the controller. The controller reports changes in the electrical parameter indicative of cut quality to the operator of the harvester via a display device thereby allowing the operator to take corrective action in harvester operation.

Abstract: A system for determining material accumulation relative to ground engaging tools of an agricultural implement includes a frame member extending along a first direction, first and second ground engaging tools coupled to the frame member, a sensing arm, a sensor, and a controller. The first and second ground engaging tools are spaced apart from each other in the first direction such that an open space is defined between the first and second ground engaging tools. The sensing arm is aligned with the open space defined between the first and second ground engaging tools and is displaceable, with the sensor being configured to detect displacement of the sensing arm. The controller is configured to monitor the displacement based at least in part on data received from the sensor to determine a presence of material accumulation between the first and second ground engaging tools.

Abstract: A system for controlling an implement during a tillage operation may include a frame and a ground-engaging tool pivotally coupled to the frame and movable relative to the frame between a retracted position and an extended position. An actuator may be configured to bias the ground-engaging tool towards the extended position during the tillage operation. An adjustable valve may be configured to permit flow out of the actuator when a fluid pressure of the actuator exceeds a reset pressure such that the actuator allows the ground-engaging tool to pivot towards the retracted position. A controller may be configured to determine at least one of an actuator position or a load value indicative of a force applied by the ground-engaging tool against the soil during the tillage operation and adjust the reset pressure based on the at least one of the actuator position or the load value.

Abstract: A system for detecting the operational status of a seed-planting implement. The system includes a row unit including a frame and a residue removal device coupled to the frame. The residue removal device is configured to remove residue from a path of the row unit. The system further includes a sensor configured to capture data indicative of at least one of a position or an acceleration of the residue removal device. The system further includes a controller configured to monitor the data received from the sensor and compare at least one monitored value associated with the at least one of the position or the acceleration of the residue removal device to a predetermined threshold value set for the residue removal device. The controller is further configured to identify the residue removal device as being plugged when the at least one monitored value differs from the predetermined threshold value.

Abstract: A spotlight controller including a housing having a first control axis, a fixed base configured to mate with the housing, the housing rotatable relative to the base about a second control axis substantially perpendicular to the first control axis, a handle configured to engage the housing and pivot about the first control axis, a housing sensor arranged to detect the position of the housing relative to the base and generate a housing position signal, a handle sensor arranged to detect the position of the handle relative to the housing and generate a handle position signal, and a controller operatively connected to the housing sensor and the handle sensor, wherein the controller receives the housing position signal and the handle position signal and generates spotlight control signals based on the housing position signal and the handle position signal.

Abstract: 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.

Abstract: In one aspect, a system for detecting plugging of an agricultural implement may a disc rotatably coupled to a frame member, with the disc configured to rotate relative to soil within a field as the implement is moved across the field. The system may also include a disc scraper coupled to the frame member, with the disc scraper configured to remove the soil from the disc as the disc rotates relative to the soil. Furthermore, the system may include a sensor configured to detect a parameter indicative of an acceleration of the disc scraper relative to frame member. Additionally, a controller of the system may be configured to monitor the acceleration of the disc scraper relative to the frame member based on data received from the sensor. Moreover, the controller may be further configured to determine when the disc is plugged based on the monitored acceleration.

Abstract: A hydraulic feed roll adjustment system includes a feed roll system, a power take off system, and at least a first controller. The feed roll system includes a feed roll, a motor and a control valve. The feed roll is positioned transversely between at least two side walls and is capable of rotation about a feed roll axis. The motor is operably connected to the fed roll and in fluid communication with a hydraulic circuit. The motor rotates the feed roll about the axis. The control value controls the rate of fluid flow through the hydraulic circuit. The power take off system includes a power take off shaft capable of rotation about a power take off axis. The at least a first controller is in electronic communications with the control value and is capable of adjusting the rotational speed of the feed roll.

Abstract: A spotlight system including a spotlight continuously rotatable about a spotlight pan axis and tiltable about a spotlight tilt axis. The system includes a spotlight controller including a housing continuously rotatable about a controller pan axis. The housing has a circumferential lip that engages with a fixed based and a hub engaged with a handle. The handle rotates about a controller tilt axis perpendicular to the controller pan axis. A controller board is electrically connected to a slip ring that penetrates the base, with a pan input sensor, a tilt input sensor, and a microprocessor. The pan input sensor measures the position of the housing relative to the base, the tilt input sensor measures the position of the handle relative to the housing, and the microcontroller interprets the positions and generates control signals corresponding to the direction of a spotlight.

Abstract: In one aspect, a method for compressing crop material for ensilage may include monitoring, with a computing device, a location of a work vehicle within a silage heap as the work vehicle traverses a layer of crop material within the silage heap. The method may also include determining, with the computing device, a current density of the layer of crop material as the work vehicle traverses the layer of crop material. Furthermore, the method may include controlling, with the computing device, an operation of the work vehicle based on the monitored location and the determined current density such that the work vehicle compresses the layer of crop material.

Abstract: In one aspect, a method for distributing crop material for ensilage may include determining, with a computing device, a storage volume for the crop material. The method may also include dividing, with the computing device, the determined storage volume into a plurality of planes. Each plane of the plurality of planes may be spaced apart from each other plane of the plurality of planes along a vertical direction. Furthermore, the method may include controlling, with the computing device, an operation of at least one of a work vehicle or an associated implement in a manner that distributes a portion of the crop material on a given plane of the plurality of planes.

Abstract: A system for actuating a boom assembly of an agricultural sprayer, the system having a frame, a boom assembly supported relative to the frame, and a linkage assembly configured to couple the boom assembly to the frame. The linkage assembly includes a support arm pivotably coupled between the frame and the boom assembly, a lift actuator pivotably coupled between the frame and the support arm and configured to raise and lower the boom assembly in a vertical direction, and a tilt actuator pivotably coupled between the frame and the boom assembly and configured to adjust a tilt angle of the boom assembly relative to the vertical direction. The system further includes a controller configured to selectively actuate the tilt actuator to adjust the tilt angle of the boom assembly to an operational tilt angle.