A system and method for irrigation, and managing irrigation of, a property or landscape. The system may include an irrigation management server (“IMS”) with the information for an irrigation system. The system may access the irrigation system that has been input into the IMS as well as access a third party map that may display the irrigation system over the map. The system may provide for a user's GPS location to be accessed through and identify the location of the user with respect to the map and irrigation overlay. The system display may provide information regarding the landscape to a user. The system may allow for manipulation of the irrigation system while overlaid on the map by the creation and manipulation of zones within the irrigation system as well as the creation and manipulation of other commands, including watering times and watering duration.

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 communicates wirelessly with irrigation control valves. A wireless controller transceiver unit obtains signals from the irrigation controller and transmits these signals wirelessly to a valve transceiver. The irrigation control valves open or close according to the signals received by the valve transceiver. The irrigation system also includes an auxiliary communication device that communicates user commands to the controller transceiver. The user commands are used to create associations between the controller transceiver and each of the valve transceivers. The communication link between the auxiliary communication device and the communication transceiver or the valve transceiver can be an RF communication link such as Bluetooth, a close field communication link such as an inductive communication link, or an optical communication link.

A system (10) may include sensor equipment (30) including one or more sensors (140, 142) disposed on a parcel of land, watering equipment (20) disposed on the parcel and configured to selectively apply water to the parcel, and a gateway (40) configured to provide for communication with the sensor equipment (30) and the watering equipment (20). The watering equipment (20) may include a watering pump (120), the watering pump (120) being operably coupled to a water source (100) and a water line (110) to alternately couple the water source (100) to and isolate the water source (100) from the water line (110), and processing circuitry (160). The processing circuitry (160) may be configured to determine an operational mode of the watering pump (120) and direct the watering pump (120) to operate in accordance with the operational mode.

A speed-control system for an irrigation system may detect when an actual speed of the irrigation system is faster or slower than a target speed of the irrigation system. In some instances, the speed-control system may detect when the actual speed is faster or slower at discrete virtual points of interest and execute compensatory measures.

A multifunctional infrared induction water sprinkler includes a water inlet pipe (10), an infrared induction control device (20) connected with the water inlet pipe (10), and a water outlet device (30), wherein the water outlet device (30) is connected with the infrared induction control device (20) through a universal joint (301); the infrared induction control device (20) includes an infrared pyroelectric probe, a pre-amplifier, a central processing unit, an electromagnetic valve actuator and an electromagnetic valve which are connected in sequence, and further includes an irrigating/repelling selection controller, a sprinkling duration regulator and a sprinkling interval regulator which are connected with the central processing unit. The multifunctional infrared induction water sprinkler can effectively repel animals to protect gardens, lawns and nursery gardens against damage and can also automatically spray water to irrigate gardens, lawns, nursery gardens and the like, and water resources can be saved.

An emitter forms a flow path that runs to a discharge part from a water collecting part for receiving an irrigation liquid in a tube. The flow path includes a flow rate control part which includes: an end surface including a concave inclined surface that faces a film for receiving the pressure of the liquid inside the tube; a hole that opens at the center of the flow volume control part and connects to the discharge part; and a groove crossing the inclined surface and running to the hole. When the film adheres to the inclined surface as a result of the pressure of the irrigation liquid inside the tube, the flow volume of the irrigation liquid inside the emitter is controlled so as to be a volume that can pass through the groove.

Some embodiments provide a system and method for interfacing with an irrigation controller based on rainfall, the system comprising: an interface unit including a housing and a control unit within the housing and configured to: cause an interruption of one or more watering schedules executed by the irrigation controller, which is separate from the interface unit, based on signaling received from a rain sensor including hygroscopic material, when a sensed expansion of the hygroscopic material is above a set rainfall accumulation threshold parameter, the rain sensor being separate from the interface unit and the hygroscopic material being configured to expand in response to being contacted by the rainfall and to contract in response to an absence of the rainfall; and remove the interruption after a completion of a predetermined interval of time after a sensed contraction of the hygroscopic material indicative of a rainfall stop.

A container garden irrigation assembly includes a reservoir for containing a fluid. A pump is positioned inside the reservoir thereby facilitating the pump to be submerged in the fluid. A control unit provided that is in electrical communication with the pump. The control unit turns the pump on and off at predetermined times of day. A pair of irrigation units is each in fluid communication with the pump to receive the fluid from the pump. Each of the irrigation units has a plurality of irrigation ports therein and each of the irrigation units is positioned over a container garden. Moreover, each of the irrigation ports is aligned with a respective one of a plurality of containers in the container garden to release the fluid into the respective container.

A smart root watering system is disclosed. The system includes a controller, configured to control the system using artificial neural networks. The system further comprises vertical tubes, inserted into the soil proximity to the roots of trees and configured to deliver water to the roots of trees. The vertical tubes include a motion sensor, configured to detect variation in water flow and wirelessly send data to the controller, thereby indicating faults of the vertical tubes to the user via a handheld electronic device. The vertical tube further includes a mechanical valve with a floater, configured to regulate input water to the system with respect to the soil absorption. The system further comprises a sensor device, configured to detect the humidity level and send to the controller. The controller is further configured to estimate the required volume of water and open an electric valve for supplying water to the roots of trees.