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.

An agricultural method includes providing a positive air pressure chamber to prevent outside contaminants from entering the chamber; growing crops in a plurality of cells in the chamber, each cell having multi-grow benches or levels, each cell further having connectors to vertical hoists for vertical movements in the chamber; maintaining pre-set temperature, humidity, carbon dioxide, watering and lighting levels to achieve predetermined plant growth; using motorized transport rails to deliver benches for operations including seeding, harvesting, grow media recovery, and bench wash; dispensing seeds in the cell with a mechanical seeder coupled to the transport rails; growing the crops with computer controlled nutrients, light and air level; and harvesting the crops and delivering the harvested crop at a selected outlet of the chamber.

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 and system for irrigating a field adjacent a watercourse is disclosed comprising a plurality of pumps along the watercourse and measuring from time to time at a plurality of measuring locations the salinity, the pH, the temperature and the turbidity of the water. The measuring locations are different from the pumping locations. A real time salinity, pH, temperature and turbidity at the pumping locations is predicted from the measured values and the pumps selectively disabled or enabled on the predicted salinity, pH, temperature and/or the turbidity.

A conveyor system (4, 5) moves vertical poles (2) in an agricultural facility between a growing area (20) and a workstation (W). Each pole carries plant growing containers (3) at multiple levels (H1-H9). An irrigation reservoir (30) may be mounted atop each pole. Irrigation lines (31-33) from the reservoir may be individually metered (35) at each level to compensate for differing water pressure with height. Sensors (40) in the reservoir and at each level of the poles may provide a controller (36) with data input. The controller may impose different growing conditions in different areas of the facility, including vertically different grow areas (20A, 20B), and controls pole movements and locations selectively to provide a sequence of poles at the workstation ready to harvest on a demand schedule. The workstation may have multiple heights (W1, W2, W3) for tall poles that increase plant density per facility footprint.

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.

In some embodiments, apparatuses and methods are provided herein useful to providing power and data to an irrigation device. In some embodiments, encoder for an irrigation control unit that provides power and data to an irrigation device over a multi-wire path comprises: an AC to DC converter to convert an input AC signal into a DC voltage; an AC signal generator to generate an output AC signal modulated with data; a control circuit to provide a modulation control signal to the AC signal generator to control generation and modulation of the output AC signal, the data modulated on the output AC signal comprising commands in accordance with irrigation programming; and a multi-wire interface coupled to the AC signal generator to electrically couple to a multi-wire path extending into a landscape and to which irrigation devices may be connected.

A tap timer and a method and system for detecting detachment of a tap timer from a faucet are provided. The method comprises measuring a first acceleration vector of the tap timer; measuring periodically a second acceleration vector of the tap timer after measuring the first acceleration vector; calculating a value based on the first acceleration vector and the second acceleration vector; and comparing the value with a predetermined value threshold to determine whether the tap timer has detached from the faucet.

Technologies disclosed herein are provided for irrigation monitoring and controlling based on water usage monitoring and control using an efficiency model for a defined geographic region. The technology includes receiving a first and a second set of moisture sensor measurements from a set of moisture sensors located in a defined geographic region, and determining an amount of water that is applied to the defined geographic region at a time period between the first and the second set of moisture measurements. An efficiency model representing efficiencies of locations in the defined geographic region is obtained based on the first and second set of moisture measurements and the amount of water applied. Schedule information is generated based on the efficiency model that indicates time periods at which areas in the defined geographic region are to be watered.

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.