An irrigation system includes: a pair of legs; an irrigation frame extending between the pair of legs and including at least one fluid conduit; a plurality of fluid dispensers configured to dispense fluid to a field, each of the fluid dispensers being fluidly coupled to the at least one fluid conduit; a trolley track coupled to the irrigation frame; and at least one trolley movably coupled to the trolley track and including a functional head configured to process plants on the field.

An autonomous agricultural carrier vehicle, for carrying an agricultural implement includes a chassis with steerable wheels or tracks attached to a frame, wherein the frame includes a mounting apparatus for connection to the agricultural implement. The vehicle further includes an environmental sensor system for determining obstacles or elements present in the vicinity of the carrier vehicle and a control device for controlling the carrier vehicle or the at least one implement, wherein the control device is connected to a position determination system that captures and issues a position to create an autonomous agricultural carrier vehicle with which the impact force is not reduced. No additional tractor vehicle is needed for the implement and no operator is necessary during field work, wherein it is provided that position-dependent working instructions for the carrier vehicle are preferably stored in the control device.

A sand bunker rake/infield groomer vehicle having a frame; a plurality of wheels to traverse a driven surface, wherein the wheels are rotatably mounted to the frame; a power source mounted to the frame; and a rear attachment structure attached to the frame, wherein the rear attachment structure provides a joint enabling rotation; a bracket including a shaft wherein the bracket is configured to cooperate with an associated rake/grooming attachment; and a pivoting bracket mounted to the frame.

A sand bunker rake/infield groomer vehicle having a frame; a plurality of wheels to traverse a driven surface, wherein the wheels are rotatably mounted to the frame; a power source mounted to the frame; and a rear attachment structure attached to the frame, wherein the rear attachment structure provides a joint enabling rotation; a bracket including a shaft wherein the bracket is configured to cooperate with an associated rake/grooming attachment; and a pivoting bracket mounted to the frame.

An automated farming system includes a frame. The frame includes a fixed base, a beam, and a support. A farming implement support extends from the beam and moves up and down in relation to the beam. The farming implement support moves along a length of the beam. The movable support includes a propulsion system and is configured to rotate around the fixed base. Movement of the farming implement support and the movable support allows for high density planting of crops in hexagonal patterns and/or a continuous spiral pattern.

An automated farming system includes a frame. The frame includes a fixed base, a beam, and a support. A farming implement support extends from the beam and moves up and down in relation to the beam. The farming implement support moves along a length of the beam. The movable support includes a propulsion system and is configured to rotate around the fixed base. Movement of the farming implement support and the movable support allows for high density planting of crops in hexagonal patterns and/or a continuous spiral pattern.

A post setting attachment for a utility vehicle includes a base having a first side mountable to the utility vehicle, the base having a second side opposing the first side of the base. The post setting attachment can include a column coupled to the second side of the base and have a length extending vertically. The post setting attachment can further include a pair of clamps attached at separate lengths along the column and configured to grasp a post. The post setting attachment can include a controller that rotates and translates the column to adjust a position of the post. Furthermore, the post setting attachment can include a gravel hopper coupled to the second side of the base that is controlled by the controller to discharge gravel after the controller adjusts the position of the post to secure the post in position.

A vehicle platform comprises a central body that can support one or more implement configurations, such as sprayer booms, or planting row units. A plurality of adjustable legs extends downward from the central body. An arm assembly has a first end and a second end opposite the first end. The first end is pivotably coupled the central body and the second end coupled to a support beam. A plurality of nozzle assemblies is supported from the support beam. An arm actuator is arranged to control a transverse position of the support beam and the nozzle assemblies with respect to a reference point on the central body, such that each nozzle assembly may be aligned with a row of seeds or plants.

Autonomous mobile field robots may be used to maintain fields. An autonomous mobile field robot may perform soil mechanics with environment sensors at a sub-region and store the soil mechanics. The robot may further determine soil temperature of the sub-region and store the soil temperature. The soil mechanics and the soil temperature are sent to a monitoring server via a radio access network for storage and analysis. The parameters for the soil of the sub-region may be adjusted based on the soil mechanics of the sub-region with the chemicals from chemical storage units. The robot may return to a home station to refill one or more of the water or chemicals.

Autonomous mobile field robots may be used to maintain fields. An autonomous mobile field robot may perform soil mechanics with environment sensors at a sub-region and store the soil mechanics. The robot may further determine soil temperature of the sub-region and store the soil temperature. The soil mechanics and the soil temperature are sent to a monitoring server via a radio access network for storage and analysis. The parameters for the soil of the sub-region may be adjusted based on the soil mechanics of the sub-region with the chemicals from chemical storage units. The robot may return to a home station to refill one or more of the water or chemicals.