A crop input applicator is provided. The crop input applicator monitors the presence of applied liquid crop in a seed trench and/or the relative placement of liquid crop and seed in a seed trench. In another aspect, the crop input applicator minimizes an offset between the liquid crop and seed placement.

An intelligent, automated system for loading agricultural product application equipment is provided in which a control system can determine a necessary amount of product for completing a field operation and can automatically couple with a tendering system to receive such product at an optimal time and location. The control system can determine a current amount of product, a projected amount of product necessary to complete a field operation and a refill amount of product from the current amount and the projected amount, then transmit the refill amount to the tender. The control system can further determine whether a position of the equipment relative to the tender is within a threshold, and whether an intake coupler of the equipment is connected to a supply coupler of the tender, and can control valve(s) to open and close channel(s) for loading fluid into the storage tank.

Various embodiments of an apparatus, methods, systems and computer program products described herein are directed to an agricultural observation and treatment system and method of operation. The system uses a pump in combination with a fluid regulator to obtain and disperse fluid from the fluid tanks. The fluid regulator includes a fluid input port, a fluid output port and a fluid control valve. A first tube fluidly coupled from the fluid pump to the fluid input port. The system includes a moveable treatment head having one or more spraying tips, including a first spraying tip. A second tube is fluidly coupled from the fluid output port to the moveable treatment head. A system includes a controller configured to provide to the fluid regulator to open and close the fluid control valve to release an amount of the first fluid.

Various embodiments of an apparatus, methods, systems and computer program products described herein are directed to an agricultural observation and treatment system and method of operation. The system uses a pump in combination with a fluid regulator to obtain and disperse fluid from the fluid tanks. The fluid regulator includes a fluid input port, a fluid output port and a fluid control valve. A first tube fluidly coupled from the fluid pump to the fluid input port. The system includes a moveable treatment head having one or more spraying tips, including a first spraying tip. A second tube is fluidly coupled from the fluid output port to the moveable treatment head. A system includes a controller configured to provide to the fluid regulator to open and close the fluid control valve to release an amount of the first fluid.

A system and methods for monitoring and evaluating the performance of a lawn-care technician. A Technician Performance Module (TPM) is affixed to or embedded in a device or apparatus used by the technician, such as a sprayer or a spreader. The TPM comprises a plurality of sensors (e.g., GPS, gyroscope, accelerometer, compass, pedometer) which collect, store, and/or transmit an assortment of data as described below. The data may be transmitted wirelessly to a control box, which may be located in a nearby vehicle, such as a truck used by the technician at the site of the lawn-care services being provided. The data also may be transmitted wireless to a cellular or wireless gateway for transmission to system servers for storage and analysis.

A computer-implemented system and method to collect and store data related to product stored in a container. In response to filling the container with the product, the following data are stored in at least one first record in an external database (such as a distributed ledger, e.g., blockchain): a product type of the first product; an amount of the first product filled into the first container; a unique identity of the first container; and a unique identity of a first user of the first container at the time of filling the first container with the first product. Data representing a unique identity of a container data module on the container are stored in the container data module. As the container moves, dispenses product, and undergoes changes in possession and ownership, data representing such events are stored in the distributed ledger and/or the container data module. As a result, a verifiable application/consumption record of the product within the container is generated.

A system for controlling a ground speed of an agricultural sprayer includes one or more sensors configured to capture data indicative of first and second application variables and a computing system communicatively coupled to the one or more sensors. In this respect, the computing system configured to determine the first and second application variables based on the data captured by the one or more sensors. Additionally, the computing system is configured to determine a spray quality index associated with the dispensing of an agricultural fluid onto a field by the agricultural sprayer based on the determined first and second application variables. Moreover, the computing system is configured to control the ground speed at which the agricultural sprayer travels across the field based on the determined spray quality index.

A system and method for managing nutrient concentrate in water-based solutions is disclosed. The method includes receiving nutrient information of water-based solution from a data measurement unit at real-time and receiving a set of desired parameters associated with the crops from one or more sources. The method further generating a set of nutrients recommendations corresponding to one or more additional nutrients required in the water-based solution for maximum crop yield and determining a set of dosing parameters to inject the one or more additional nutrients in the water-based solution based on the nutrient information, the set of desired parameters and the set of nutrients recommendations by using a nutrient management based AI model. Further, the method includes the nutrient information, the set of desired parameters, the set of nutrients recommendation and the set of dosing parameters on user interface screen of one or more electronic devices.

Disclosed is a nonlimiting example of a manifold assembly. In example embodiments the manifold assembly may include a manifold bowl, a manifold cover over the manifold bowl, a manifold plate having a plurality of holes, a restraint structure configured to prevent the manifold plate from translating and overturning, and an actuator configured to rotate the manifold plate. In one nonlimiting example embodiment the manifold cover has a plurality of holes and a plurality of hose barbs aligned with the plurality of holes. In this nonlimiting example embodiment the plurality of holes in the manifold plate are alignable with the plurality of holes in the manifold cover. In at least one nonlimiting example embodiment, rotating the manifold plate aligns and misaligns the holes in the manifold plate and the holes in the manifold cover.

An electronic device is described, including memory and a processor coupled to the memory. The processor is configured to receive center pivot irrigation system information corresponding to a center pivot irrigation system and to request map data. The processor is also configured to a user interface with a map of the center pivot irrigation system. The processor is further configured to receive an input via the user interface indicating an input point. The processor is additionally configured to render an alteration point marker at a first position, the alteration point marker representing an alteration point for the pivot, the alteration point corresponding to a first radial position of the pivot at which a change in operation of the pivot is set to occur. The processor is also configured to control the center pivot irrigation system to alter operation of the pivot at the first radial position.