Some embodiments provide methods and systems of controlling irrigation. Some of these systems comprise: a connector of a controller interface (CI) coupled with an irrigation controller, wherein the connector is configured to receive a valve activation signal activated by the irrigation controller; a
Some embodiments provide methods and systems of controlling irrigation. Some of these systems comprise: a connector of a controller interface (CI) coupled with an irrigation controller, wherein the connector is configured to receive a valve activation signal activated by the irrigation controller; a user interface of the CI; a processor of the CI configured to obtain valve transceiver (VT) programming with VT programming being received from inputs through the user interface, determine a station identifier, and identify as defined in the VT programming a remote valve associated with the station identifier and controlled by a remote VT; and a wireless transceiver configured to wirelessly transmit a wireless activation signal configured to be wirelessly received by the VT controlling the valve associated by the VT programming with the station identifier such that the VT is configured to control an actuator to actuate the valve.
대표청구항▼
1. An irrigation system, comprising: a connector of a controller interface (CI) coupled with an irrigation controller, wherein the connector is configured to receive a valve activation signal activated by the irrigation controller;a user interface of the CI;a processor of the CI coupled with the con
1. An irrigation system, comprising: a connector of a controller interface (CI) coupled with an irrigation controller, wherein the connector is configured to receive a valve activation signal activated by the irrigation controller;a user interface of the CI;a processor of the CI coupled with the connector and the user interface, wherein the processor is configured to obtain valve transceiver (VT) programming with at least a portion of the VT programming being received from inputs by a user through the user interface of the CI, determine a station identifier as a function of the valve activation signal, and identify as defined in the VT programming a remote valve associated with the station identifier of the irrigation controller and controlled by a remote VT; anda wireless transceiver coupled with the processor and configured to wirelessly transmit a wireless activation signal configured to be wirelessly received by the VT controlling the valve associated by the VT programming with the station identifier such that the VT is configured to control an actuator to actuate the valve. 2. The irrigation system of claim 1, wherein the processor in obtaining the VT programming is configured to associate the VT with the valve controlled by the VT and associated with the station identifier designated by the valve activation signal. 3. The irrigation system of claim 1, wherein the processor is further configured communicate a query to the irrigation controller, wherein the connector in receiving the valve activation signal activated by the irrigation controller is configured to receive a response to the query, and wherein the processor determines the station identifier from the response to the query. 4. The irrigation system of claim 1, wherein the processor is configured to receive, from the inputs through the user interface, direction information as part of the VT programming, wherein the direction information identifies a designated geographic direction from a location of the CI toward the VT with which the VT programming information is associated. 5. The irrigation system of claim 1, wherein the processor is configured to evaluate the valve activation signal received from the irrigation controller to identify the station identifier, identify as a function of the valve activation signal and the station identifier the valve to be activated in accordance with the valve activation signal, identify the VT corresponding to the valve to be activated, and activate the wireless transceiver to wirelessly transmit the wireless activation signal in response to identifying the VT to activate the corresponding one or more identified remote valves. 6. The irrigation system of claim 1, wherein the connector comprises a plurality of station input terminals configured to couple with station output terminals of the irrigation controller intended to be directly wired with a valve actuator such that the valve activation signal when applied to a station output terminal in accordance with an irrigation schedule implemented by the irrigation controller is received at a corresponding station input terminal, and wherein the processor is configured to associate in the VT programming the input terminal with the valve to be activated upon detecting a valve activation signal on the input terminal. 7. The irrigation system of claim 1, wherein the connector is configured to couple with a communication port of a control panel of the irrigation controller to receive the valve activation signals directly from the control panel. 8. The irrigation system of claim 1, wherein the processor of the CI is further configured to receive sensor data from a remote sensor, determine whether a threshold associated with the sensor data is exceeded and interrupt irrigation from the one or more valves controlled by the VT when the threshold associated with the sensor data is exceeded. 9. The irrigation system of claim 8, wherein the processor of the CI is further configured to interrupt all irrigation associated with the irrigation controller for at least a predefined period of time in response to determining that the threshold associated with the sensor data is exceeded. 10. The irrigation system of claim 1, wherein the processor is configured to obtain the remote VT programming independent of programming of the irrigation program at the irrigation controller. 11. The irrigation system of claim 1, wherein the wireless transceiver is configured to receive status information from the VT regarding a parameter of the VT; and the processor is further configured to determine whether the status information has a predefined relationship with a corresponding status threshold, and cause a beeper command to be wirelessly communicated to the VT to generate an audible alert in response to determining that the status information has the predefined relationship with a corresponding status threshold. 12. The irrigation system of claim 1, further comprising: a main circuit board of the CI, the main circuit board comprising the processor and an interface board connector, wherein the interface board connector is configured to interchangeably connect the main board with one of multiple different interface boards having the connector, wherein the connector is different on the different interface boards to allow the CI to be implemented in different configurations. 13. A method of irrigating, comprising: receiving, at a connector of a controller interface (CI) coupled with an irrigation controller, a valve activation signal activated by the irrigation controller, wherein the valve activation signal corresponds to a station identifier programmed at the irrigation controller;identifying, at a processor of the CI, a remote valve associated with the station identifier as defined at the CI in valve transceiver (VT) programming wherein at least a portion of the VT programming is received from inputs by a user through a user interface of the CI coupled with the processor, wherein the VT programming associates the station identifier with the remote valve controlled by an associated VT; andwirelessly transmitting a wireless activation signal to the associated VT, wherein the associated VT is configured to control an actuator to actuate the remote valve. 14. The method of claim 13, wherein the obtaining the VT programming comprises associating the VT with the station identifier and a valve designation corresponding to the valve controlled by the VT. 15. The method of claim 14, wherein the obtaining the VT programming comprises: receiving, from the inputs by the user through the user interface, the station identifier of the irrigation controller; andassociating the station identifier with a valve designation corresponding to the valve controlled by the VT as part of the remote VT programming. 16. The method of claim 14, wherein the obtaining the VT programming comprises: receiving, from the inputs through the user interface, direction information representing a designated geographic direction toward the VT with which the remote VT programming information is associated; andassociating the direction information with a VT identifier. 17. The method of claim 13, further comprising: querying, from the CI, the irrigation controller; andwherein the receiving the valve activation signal comprises receiving, at the CI, a response to the query from the irrigation controller and identifying from the response the station identifier. 18. The method of claim 17, wherein the response comprises status information indicating a valve with an on status corresponding to the station identifier; wherein the identifying the remote valve associated with the station identifier comprises evaluating, at the CI, the status information to identify the station identifier. 19. The method of claim 18, wherein the wirelessly transmitting the wireless activation signal comprises broadcasting the wireless activation signal comprising an activation listing that identifies a state of multiple valves controlled through the CI including the on state of the valve associated with the station identifier. 20. The method of claim 13, wherein the identifying the remote valve comprises: identifying an input terminal of the CI that couples with a station output terminal of the irrigation controller and through which the valve activation signal is received; andidentifying the valve associated with the input terminal and through which the valve activation signal is received. 21. The method of claim 13, wherein the identifying the one or more remote valve comprises: receiving the valve activation signal through the connector coupled with a communication port of a control panel of the irrigation controller; andevaluating in the CI the valve activation signal to identify the station identifier specified in accordance with the valve activation signal and the valve as defined in the VT programming associated with the station identifier. 22. A method of controlling irrigation, comprising: identifying, at a controller interface (CI) coupled with an irrigation controller, a remote valve transceiver (VT), wherein the CI is separate from the VT and the CI is configured to wirelessly communicate wireless activation signals to the VT;displaying, on a display of the CI, an identification of the VT; anddisplaying, on the display of the CI, a valve station designator corresponding to a valve controlled by the VT. 23. The method of claim 22, further comprising: receiving a station number through a user interface of the CI that is separate from the irrigation controller, wherein the station number is consistent with a station number defined within an irrigation program stored in and implemented by the irrigation controller; andassociating, at the CI, the station number according to the irrigation program with the valve station designator. 24. The method of claim 22, wherein the displaying the valve station designator comprises displaying the valve station designator corresponding to an input terminal of the CI with which a user is to couple with a station output terminal of the irrigation controller, the station output terminal corresponding to a station defined within the irrigation program to be activated when the irrigation controller issues a station activation signal on the station output terminal in accordance with the irrigation program. 25. The method of claim 22, further comprising: displaying, on the display of the CI, a direction designation interface configured to allow a user to designate a direction from the CI toward the VT;receiving, through the user interface of the CI while the direction designation interface is displayed, a direction designation designating the direction from the CI toward the VT; andassociating, at the CI, the direction designation with the VT. 26. The method of claim 22, further comprising: receiving, at the CI, status information regarding parameters of the VT;determining, at the CI, whether the status information has a predefined relationship with a corresponding status threshold; andwirelessly communicating from the CI an alert activation signal to the VT in response to determining that the status information has the predefined relationship with the corresponding status threshold, wherein the alert activation signal is configured to cause the VT to activate an audible element at the VT to generate an audible alert. 27. A method of controlling irrigation, the method comprising: querying, from a controller interface (CI), an irrigation controller, wherein the CI is communicationally coupled with the irrigation controller;receiving, at the CI, a response to the query;generating at the CI a wireless activation signal as a function of the response to the query; andwirelessly transmitting the wireless activation signal to a valve transceiver (VT) configured to receive the wireless activation signal to control an actuator to actuate a valve. 28. The method of claim 27, wherein the receiving the response to the query comprises receiving status information from the irrigation controller identifying a status that the valve should be active; and wherein the wirelessly transmitting the wireless activation signal comprises broadcasting the wireless activation signal comprising an activation listing that identifies a state of multiple valves controlled through the CI.
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이 특허에 인용된 특허 (127)
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