A system for adjusting penetration depth settings of seed planting units of an agricultural implement, the system may include a plurality of seed planting units and a common drive assembly. Each of the seed planting units may have a depth adjustment assembly. The common drive assembly may be configured to drive the depth adjustment assemblies of the plurality of seed planting units so as to simultaneously adjust a penetration depth setting of each respective seed planting unit.

A system for adjusting penetration depth settings of seed planting units of an agricultural implement, the system may include a plurality of seed planting units and a common drive assembly. Each of the seed planting units may have a depth adjustment assembly. The common drive assembly may be configured to drive the depth adjustment assemblies of the plurality of seed planting units so as to simultaneously adjust a penetration depth setting of each respective seed planting unit.

A mobile machine includes a frame, and a set of wheels supporting the frame. The mobile machine also includes a set of ground-engaging tools mounted to the frame that are movable relative to the wheels to change a depth of engagement of the ground engaging-tools with ground over which the mobile machine travels. A first sensor senses a position of the frame relative to the ground surface over which the mobile machine is traveling. A second sensor senses a position of the frame relative to the wheels. The sensor signals from both sensors are used to control the frame height.

In one aspect, a system for determining soil clod size distribution as an agricultural implement is being towed across a field by a work vehicle may include a vision-based sensor provided in operative association with one of the work vehicle or the agricultural implement. As such, the vision-based sensor may be configured to capture vision data associated with a portion of the field present within a field of view of the vision-based sensor. Furthermore, the system may include a controller configured to receive vision data from the vision-based sensor. Moreover, the controller may be further configured to analyze the received vision data using a spectral analysis technique to determine a size distribution of soil clods present within the field of view of the vision-based sensor.

In one aspect, a system for determining soil clod size distribution as an agricultural implement is being towed across a field by a work vehicle may include a vision-based sensor provided in operative association with one of the work vehicle or the agricultural implement. As such, the vision-based sensor may be configured to capture vision data associated with a portion of the field present within a field of view of the vision-based sensor. Furthermore, the system may include a controller configured to receive vision data from the vision-based sensor. Moreover, the controller may be further configured to analyze the received vision data using a spectral analysis technique to determine a size distribution of soil clods present within the field of view of the vision-based sensor.

In one aspect, a system for regulating the flow of fluid supplied to actuators of an agricultural implement may include a tool and a fluid-driven actuator configured to actuate the tool relative to a surface. The system may also include a pump configured to supply fluid to the fluid-driven actuator and a valve configured to control a flow of the fluid supplied to the fluid-driven actuator. Furthermore, the system may include a first sensor configured to detect a parameter indicative of a first pressure upstream of the valve and a second sensor configured to detect a parameter indicative of a second pressure downstream of the valve. Additionally, the system may include a controller communicatively coupled to the first and second sensors, with the controller configured to determine a pressure differential across the valve based on measurement signals received from the first and second sensors.

In one aspect, a system for regulating the flow of fluid supplied to actuators of an agricultural implement may include a tool and a fluid-driven actuator configured to actuate the tool relative to a surface. The system may also include a pump configured to supply fluid to the fluid-driven actuator and a valve configured to control a flow of the fluid supplied to the fluid-driven actuator. Furthermore, the system may include a first sensor configured to detect a parameter indicative of a first pressure upstream of the valve and a second sensor configured to detect a parameter indicative of a second pressure downstream of the valve. Additionally, the system may include a controller communicatively coupled to the first and second sensors, with the controller configured to determine a pressure differential across the valve based on measurement signals received from the first and second sensors.

A system that includes a wheel carrier system. The wheel carrier system includes a wheel carrier arm that couples to a wheel and to a wheel carrier frame. A link rotates a ground engaging tool system with respect to a row unit to transition the ground engaging tool system from a lowered position to a raised position. An actuator that simultaneously rotates the first wheel carrier arm from a first position to a second position and the ground engaging tool system from the lowered position to the raised position.

A system that includes a wheel carrier system. The wheel carrier system includes a wheel carrier arm that couples to a wheel and to a wheel carrier frame. A link rotates a ground engaging tool system with respect to a row unit to transition the ground engaging tool system from a lowered position to a raised position. An actuator that simultaneously rotates the first wheel carrier arm from a first position to a second position and the ground engaging tool system from the lowered position to the raised position.

An automatic terrain adjustment system automatically adjusts the forward and rearward height of a tractor-towed agricultural implement, such as a defoliator, responsive to a sensed change in the depth of terrain over which the agricultural implement traverses. The forward height of the implement is adjusted independently of the rearward height of the implement using two distinct automatic depth controlling systems. Each automatic depth controlling system utilizes a linkage in conjunction with a sensing wheel and hydraulic valve to control either a rear actuator, which adjusts a height of a rear axle of the implement, or a forward actuator, which adjusts a height of the front of the implement.