Disclosed embodiments can provide a system and method for controlling irrigation schedules for a sprinkler system for at least one irrigation zone. The embodiments include automatically updating irrigation schedules based at least in part on watering restriction data from a water authority, such as a water utility authority, and water usage data for a property including the at least one irrigation zone.

A method for managing a zone characteristics (e.g., for irrigation zones) including presenting on a user device a first user interfacing including a plurality of vegetation icons indicative of a type of vegetation growing within a first zone, receiving a first user selection of a vegetation for the first zone via selection by the user of a particular vegetation icon of the plurality of vegetation icons, presenting a second user interface including a plurality of exposure icons corresponding to a level of sun exposure for the first zone, receiving from the user device a second user selection of exposure for the first zone via selection by the user of a particular exposure icon of the plurality of exposure icons, and generating by a central controller in communication with the user device, a first zone profile based on the first user selection and the second user selection.

An irrigation column for a drip irrigation system has a fluid conducting line for receiving fluid from a fluid source upstream. The irrigation column further includes a plurality of drip line segments extending alongside the fluid conducting line, a plurality of zone valves located along the fluid conducting line, and a plurality of control tubes extending alongside the fluid conducting line. And each control tube is in fluid communication with a respective one of the zone valves for actuating the zone valve.

An irrigation system comprises an irrigation controller that receives user input and provides a power signal and command and message data to an encoder. The encoder encodes the command and message data onto the power signal to provide a data encoded power waveform that is sent over a two-wire path. The irrigation system further comprises one or more decoders in communication with the two-wire path to receive the data encoded power waveform and one or more irrigation valves in communication with the one or more decoders. The data encoded power waveform provides power to the decoders and the decoders decode the command and message data from the data encoded power waveform to control the irrigation valves according to the user input.

An adaptive hydraulic control system controls irrigation system zones using predicted valve behavior, measured pressure, recovery time, and measured flow. A pressure sensor can measure a pressure in a water line and a flow meter can measure a flow rate in the water line. The adaptive hydraulic control system monitors the pressure and the flow rate, and determines when the pressure and the flow rate are above and below target operational thresholds. When the pressure is determined to be below a minimum target threshold or the flow rate is determined to be above a maximum target threshold, the adaptive hydraulic control system identifies one or more valves in an opened position of the plurality of valves that when closed would cause the pressure and the flow rate to return within the target operational thresholds. The adaptive hydraulic control system provides instructions to change a position of the one or more identified valves.

Systems and method for coordinating movements of agricultural machines and irrigation systems on irrigated fields to avoid collisions and other interferences between the equipment may be implemented with a mobile irrigation system, a number of agricultural machines, and a processing system. The processing system receives and analyzes data from an irrigation schedule for the irrigation system and location data from the agricultural machines to detect possible interferences between the equipment and takes corrective action if likely interferences are detected.

An irrigation system comprises an irrigation controller that receives user input and provides a power signal and command and message data to an encoder. The encoder encodes the command and message data onto the power signal to provide a data encoded power waveform that is sent over a two-wire path. The irrigation system further comprises one or more decoders in communication with the two-wire path to receive the data encoded power waveform and one or more irrigation valves in communication with the one or more decoders. The data encoded power waveform provides power to the decoders and the decoders decode the command and message data from the data encoded power waveform to control the irrigation valves according to the user input.

An irrigation system comprises an irrigation controller that receives user input and provides a power signal and command and message data to an encoder. The encoder encodes the command and message data onto the power signal to provide a data encoded power waveform that is sent over a two-wire path. The irrigation system further comprises one or more decoders in communication with the two-wire path to receive the data encoded power waveform and one or more irrigation valves in communication with the one or more decoders. The data encoded power waveform provides power to the decoders and the decoders decode the command and message data from the data encoded power waveform to control the irrigation valves according to the user input.

A decision-making method for variable rate irrigation management includes the following steps: S1: sampling a soil from a root zone of a crop in an area controlled by an irrigation sprinkler, and measuring compositions of separates of the sampled soil; S2: managing and dividing the area controlled by the irrigation sprinkler according to an AWC of the soil in the root zone of the crop; S3: constructing an optimized soil moisture sensor network; S4: placing ground-fixed canopy temperature sensors; S5: constructing an optimized airborne canopy temperature sensor network centered on the center pivot; and S6: performing a variable rate irrigation by using the optimized soil moisture sensor network, the fixed canopy temperature sensors, the optimized airborne canopy temperature sensor network and an automatic weather station. The method optimizes the placement and quantity of the soil moisture sensor network and the canopy temperature sensor network to improve the measurement accuracy.

An irrigation solenoid valve switch assembly is operable on a mesh network. The assembly uses a mesh network to transmit valve command signals that control the timing and amount of water discharged through a solenoid valve in multiple agricultural zones. A solenoid valve regulates the flow of water. A clock, or agricultural controller, generates valve command signals that control the timing and amount of water discharged through the solenoid valve. A hub controller operatively connects to the clock. The hub controller transmits the valve command signals over the mesh network. A switch operatively connects to the solenoid valve. The switch receives the valve command signals to control the solenoid valve, in correspondence to the valve command signals. The switch has a rechargeable battery that feeds direct current to the switch for operation of the solenoid valve. Multiple relay signal repeaters carry the valve command signals across the mesh network.