A system may include a sensor disposed on a parcel of land, watering equipment comprising a watering pump and processing circuity, and a user terminal comprising a user interface. The sensor may be configured to detect moisture conditions. The processing circuitry may be configured to direct the watering pump to operate in accordance with an operational mode. The user terminal may be configured to output system information via the user interface based on sensor data provided by the sensor, control the watering pump to operate in accordance with the operational mode, and delegate operational control of the system to a second user in response to a delegation input provided by a first user via the user interface.

The present invention provides a method and a device for iris recognition. By providing a sensing unit under the iris recognition region of the display unit, the invention can capture the iris information of the user's eyeball in time, and then compare with the presetting iris information, and execute the operation instruction corresponding to the iris information, thereby effectively improving the precision of the iris recognition. In addition, the sensing unit is disposed under the display unit, and the overall thickness of the mobile device can be effectively reduced compared with the structure in which the camera is protruded and disposed independently outside the region of the display screen, so that the wearable device or the mobile device is thinner and more suitable for flexible wearable devices or mobile devices, to meet the needs of the market.

In some embodiments, provide an irrigation sensor system, comprising: a rain funnel comprising an upper opening and at least one wall tapering from the upper opening to a lower aperture; and a tipping bucket positioned to receive water falling from the lower aperture while the tipping bucket is positioned such that a central longitudinal axis of the tipping bucket is not aligned with an axis extending through the lower aperture of the funnel.

A digital water timer may include a main body, a water valve, a locating base, a driving base, and a timer. The main body has a water inlet and a water outlet, and a valve tube protrudes from a lateral side of the main body. The water valve connected to the main body is controlled by the timer to achieve on/off operation of channels inside the main body. The locating base is secured on the main body, and the driving base is adapted to have rotation relative to the locating base and be secured at a specific position after rotated. The timer installed in the driving base comprises a display panel and an operation interface which are exposed externally for operation. The driving base with the timer is rotated relative to the locating base, and the display panel is adjusted as needed to provide an optimal view for operation.

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 landscape control box includes a base portion and a facepack. The facepack supports a rotary shaft extending along an axis in a first direction. A cover has a hole aligned with the rotary shaft. A knob has a receptacle and a first portion of an interacting structure. The receptacle engages with the rotary shaft so as to transfer rotational motion of the knob to the rotary shaft. The first portion of the interacting structure engages with a second portion of the interacting structure on the cover so as to inhibit movement of the knob. The control box can receive one or more modules for enhancing functionality of the control box and/or superseding station programming stored by the control box or input by the user. The control box includes openings that are sized and shaped to allow attachment of different sized pipes and conduits to the control box.

A hydration system for an indoor gardening appliance includes a pressurized water supply including a pump assembly for pressurizing an accumulator and an auxiliary nozzle in fluid communication with the pressurized water supply. An auxiliary valve assembly is operably coupled to the auxiliary nozzle for selectively directing an auxiliary flow of water from the accumulator onto the plant pods when power is lost to the gardening appliance.

A turf management system includes a wireless receiver that is configured to receive respective wireless signals comprising sensor data from wireless sensors positioned in a soil profile at respective depths below a green surface. A control circuit is coupled to the wireless receiver and is configured to determine soil profile conditions at the respective depths below the green surface responsive to the sensor data. The control circuit is coupled to a subsoil environmental control mechanism and is configured to automatically control operation of the subsoil environmental control mechanism responsive to the soil profile conditions at the respective depths below the green surface. The subsoil environmental control mechanism may include a hydronic mechanism that is configured to circulate fluid through a hydronic tubing network below the green surface.

In some embodiments, a method includes receiving, by a wireless component of a wireless valve switch system via a wireless network, wireless instructions and causing, by the wireless component based on the wireless instructions, actuation of a sprinkler valve. In some embodiments, a wireless valve switch system includes a wireless component configured to be electrically coupled to a sprinkler valve. The wireless component includes a controller to receive, via a wireless network, wireless instructions and cause, based on the wireless instructions, actuation of the sprinkler valve. In some embodiments, a wireless valve switch system includes a turbine component that includes a casing forming a chamber configured to be fluidly coupled to a sprinkler valve. The turbine component further includes a turbine disposed in the chamber and configured to rotate responsive to fluid flow through the chamber to power an electrical component configured to be electrically coupled to the sprinkler valve.

Disclosed herein are embodiments of a device that is useful for drip irrigation. The device comprises a drip line connection unit, a valve and a measurement unit that counts water drops. And the device may further comprise a control unit. The device attached to a drip irrigation line and produces water drops of a known size, counts the number of drops to determine the volume of water being applied, and shuts off the water flow once a desired amount of water has been provided.