A mobile tower for use with an irrigation system having horizontally-extending spans, the mobile tower comprising a frame and a number of wheels. The frame includes a crossbeam, first and second diagonal legs, first and second lower gussets, and an upper bracket. The crossbeam, first diagonal leg, and second diagonal leg include tubular members having gusset connectors. The tubular members are interchangeable and adaptable with other tubular members.

A tilt monitoring system for a mobile irrigation system including a sensor and a controller. The sensor is configured to detect a tilt magnitude of the span and generate a corresponding tilt signal. The controller is configured to receive the tilt signal representing the tilt magnitude, generate a deactivation signal representing an instruction to deactivate the drive motor if the tilt magnitude is greater than a tilt threshold, transmit the deactivation signal to the drive motor, generate a notification signal representing a notification that the drive motor has been deactivated due to the tilt magnitude, transmit the notification signal, receive a follow-up input signal representing a follow-up input, generate a follow-up command signal representing a command for implementing the follow-up input, and transmit the follow-up command signal so that the mobile irrigation system implements the follow-up input.

A system for measuring moisture in soil below the ground surface comprises at least one passive microwave sensor device configured to measure natural thermal emissions from the soil and output a data signal and a processing circuit operably coupled to the at least one passive microwave sensor wherein the processing circuit is configured to receive the data signal and compile a soil moisture profile. The system further comprises a wide-band antenna wherein the at least one passive microwave sensor is located therein and an elongate horizontal mounting frame extending between first and second ends wherein the first end is securable to a mobile agricultural device and wherein the wide-band antenna is secured to the second end so as to position the wide-band antenna at a distance above the ground surface.

A device detects a trigger to dispense a product at a using a tool operably coupled to a tractor. The device determines whether the tractor is in an automated mode, the automated mode enabling autonomous speed and direction navigation of the tractor. Responsive to determining that the tractor is not in the automated mode, the device determines whether the tool is in a ready state, and responsive to determining that the tool is in the ready state, commands the tool to dispense the product, wherein the tool is not commanded to dispense the product until the tool is in the ready state. Responsive to determining that the tractor is in the automated mode, the device commands the tool to dispense the product without determining whether the tool is in the ready state.

Novel tools and techniques are provided for implementing Internet of Things (“IoT”)-based microwell solution for irrigation. In various embodiments, in response to receiving, from the plurality of sensors, first sensor data indicative of environmental conditions within an area, a computing system may analyze the first sensor data to determine parameters associated with water requirements within the area, may generate a water distribution plan based at least in part on the determined parameters, and may map the generated water distribution plan to a positional map of a plurality of microwells disposed at pre-installed locations within the area. The computing system may generate and send instructions to the microwells to pump water from an underground water source(s) (in some cases, surface water sources as well) and to irrigate plants or crops in the area using integrated irrigation systems, based on the mapping. The microwells and sensors may utilize IoT functionalities.

An agricultural sprayer includes a boom assembly having first and second wing boom sections. Additionally, the sprayer includes an actuator configured to adjust a fore/aft tilt angle of the boom assembly, with the fore/aft tilt angle defined between a central axis of the boom assembly and a vertical direction. Moreover, the sprayer includes a sensor configured to capture data associated with a position of the second boom section relative to the first boom section. In this respect, a computing system is configured to determine an angle defined between the first and second boom sections or a height of a tip of the second boom section based on the data captured by the sensor. In addition, the computing system is configured to control an operation of the actuator to adjust the fore/aft tilt angle of the boom assembly based on the determined angle or the determined height.

An agricultural sprayer includes a boom assembly having first and second wing boom sections. Additionally, the sprayer includes an actuator configured to adjust a fore/aft tilt angle of the boom assembly, with the fore/aft tilt angle defined between a central axis of the boom assembly and a vertical direction. Moreover, the sprayer includes a sensor configured to capture data associated with a position of the second boom section relative to the first boom section. In this respect, a computing system is configured to determine an angle defined between the first and second boom sections or a height of a tip of the second boom section based on the data captured by the sensor. In addition, the computing system is configured to control an operation of the actuator to adjust the fore/aft tilt angle of the boom assembly based on the determined angle or the determined height.

A farming system includes a field engagement unit. The field engagement unit includes a support assembly. The support assembly includes one or more work tool rail assemblies. The field engagement unit additionally includes one or more propulsion units which provide omnidirectional control of the field engagement unit. The field engagement unit additionally includes one or more work tool assemblies. The one or more work tool assemblies are actuatable along the one or more work tool rail assemblies. The farming system additionally includes a local controller. The local controller includes one or more processors configured to execute a set of program instructions stored in memory. The program instructions are configured to cause the one or more processors to control one or more components of the field engagement unit.

A farming system includes a field engagement unit. The field engagement unit includes a support assembly. The support assembly includes one or more work tool rail assemblies. The field engagement unit additionally includes one or more propulsion units which provide omnidirectional control of the field engagement unit. The field engagement unit additionally includes one or more work tool assemblies. The one or more work tool assemblies are actuatable along the one or more work tool rail assemblies. The farming system additionally includes a local controller. The local controller includes one or more processors configured to execute a set of program instructions stored in memory. The program instructions are configured to cause the one or more processors to control one or more components of the field engagement unit.

The present invention provides a system and method for calculating the water flow rates applied by corner arm sprinklers. According to a first embodiment, the present invention provides a system and method for controlling and balancing the flow rates of corner arm sprinklers to provide targeted discrete, controlled uniform and non-uniform water distribution rates across a given field.