A valve body has a piston that slides within the body through four successive positions. The piston has a head, and an upper and lower skirt, with a port in the upper skirt. In the first position, a bias force urges the piston to the first of four positions, in which the piston port is closed. In a second position, the piston port aligns with a low pressure port in the valve body, when a low pressure supply of water is connected. In a third position, greater pressure again closes the piston port. In a fourth position, at a still greater pressure, the piston port aligns with a high pressure port in the valve body. The bias force or a location of the piston port can be varied for valves along a supply line, whereby varying supply pressure opens different valves, thereby enabling addressing of valves according to supply pressure.

A flow control center can include a barometric sensor, at least one ball valve assembly, and a computing device. The ball valve can be controllable among a plurality of discreet positions to selectively change a flow of fluid. The computing device can have a communication device configured to receive signals from the barometric sensor. The computing device can determine a first flow rate in response to the sensed pressure represented by the first signal. The computing device can also control a motor of the ball valve assembly to move a ball valve to a first of the plurality of discreet angular positions. The first of the plurality of discreet angular positions can correspond to the sensed pressure represented by the first signal.

A valve body has a piston that slides within the body through four successive positions. The piston has a head, and an upper and lower skirt, with a port in the upper skirt. In the first position, a bias force urges the piston to the first of four positions, in which the piston port is closed. In a second position, the piston port aligns with a low pressure port in the valve body, when a low pressure supply of water is connected. In a third position, greater pressure again closes the piston port. In a fourth position, at a still greater pressure, the piston port aligns with a high pressure port in the valve body. The bias force or a location of the piston port can be varied for valves along a supply line, whereby varying supply pressure opens different valves, thereby enabling addressing of valves according to supply pressure.

Disclosed embodiments can provide a system and method for controlling irrigation schedules for a sprinkler system including automatically updating irrigation schedules based on qualitative and quantitative feedback and meteorological data as well as matching optimal or near-optimal irrigation schedules to other sprinkler zones based on characteristics of the landscape and sprinkler system as well as other characteristics.

A decoder for a two-wire irrigation system is disclosed, having the ability to be remotely updated with new firmware over the two-wire network, the ability to download irrigation commands that can be executed at a later time, the ability to adjust its data speed when data corruption is encountered, and the ability to sense the position of an attached solenoid plunger.

Disclosed embodiments can provide a system and method for controlling irrigation schedules for a sprinkler system including automatically updating irrigation schedules based on qualitative and quantitative feedback and meteorological data as well as matching optimal or near-optimal irrigation schedules to other sprinkler zones based on characteristics of the landscape and sprinkler system as well as other characteristics.

A latching solenoid slave valve for wirelessly receiving watering instructions from an irrigation controller via acoustical waves or pulses. The latching solenoid slave valve comprises a diaphragm in direct communication with a main water distribution conduit of the irrigation system for detecting acoustical waves or pulses transmitted by pressurized water of the main water distribution conduit. An accelerometer is supported by the diaphragm for generating an output signal as the diaphragm vibrates due to detection of the acoustical waves or pulses. A microcontroller is electrically coupled to the accelerometer for processing the output signals of the accelerometer, and the microcontroller determining, from the processed output signals of the accelerometer, whether or not the latching solenoid slave valve is to commence a watering cycle for a desired duration of time. An irrigation controller is wirelessly coupled to the latching solenoid slave valve for controlling operation thereof.

A method of operating a drip irrigation system is provided and includes providing drip irrigation lines aside a diverter line with T-junctions interleaved between adjacent ones of the drip irrigation lines and each T-junction including a three-way line coupled to the diverter line, a check valve operably disposable between the three-way line and a downstream end of an upstream one of the drip irrigation lines to permit fluid flow in only a forward direction and a controllable valve operably disposable between the three-way line and an upstream end of a downstream one of the drip irrigation lines.

An irrigation system is provided and includes a main irrigation line, one or more lateral driplines, each lateral dripline being divided into zones and including a plurality of emitters at each zone and a plurality of controllable valves disposed along each of the one or more lateral driplines at zone borders. Each one of the plurality of controllable valves is actuatable to activate corresponding emitters in the associated zone in a zone by zone cycle and each one of the plurality of emitters is replaceable to vary an amount of deliverable fluid by the zone by zone cycle.

An irrigation system is provided and includes a main irrigation line, one or more lateral driplines, each lateral dripline being divided into zones and including a plurality of emitters at each zone and a plurality of controllable valves disposed along each of the one or more lateral driplines at zone borders. Each one of the plurality of controllable valves is actuatable to activate corresponding emitters in the associated zone in a zone by zone cycle and each one of the plurality of emitters is replaceable to vary an amount of deliverable fluid by the zone by zone cycle.