An irrigation management system monitors irrigation parameters, including progress of flood irrigation water admitted onto a farm field, water levels in ditches, basins or boxes, soil moisture, water usage and other important factors. In flood irrigation a series of small, inexpensive sensors detect the presence in each of the sensor locations in a field, and each sends a signal when water first reaches the sensor. In a preferred form the sensor communicates by long-range radio communication either directly with a hub or gateway, or by sending a transmission that is relayed from location to location and ultimately to the hub or gateway. All aspects of irrigation water need, availability, task completion, pipe and equipment status, and water usage are monitored and communicated to the farmer. The system allows efficient water management and reliable and responsible irrigation at all irrigated fields.

Disclosed is a wall landscaping system for easy growth management with automatic watering and plant growth analysis, which creates a vertical garden on an interior or exterior wall of a structure, the system including: a main body (10) installed to cover the wall (W) to have a plant grown thereon; a watering part (20) disposed at an upper end of the main body (10) to supply water to the plant; a detector (30) disposed around the main body (10) to photograph the plant; and a controller (40) automatically checking and recording a growth state of the plant by analyzing an image photographed by the detector (30), and remotely notifying a manager according to the growth state of the plant, whereby it is possible to automatically supply water at a predetermined interval for each plant, and analyze the growth state of the plant and notify the same.

Devices, systems, and methods for providing and operating a pump control module and one or more pumps in an assembly line grow pod are provided herein. Some embodiments include the assembly line grow pod having one or more pumps, a master controller with a plurality of bays and being communicatively coupled to the pumps, and a pump control module within one of the bays such that the pump control module is communicatively coupled to the master controller and the pumps. The pump control module is programmed to receive information regarding fluid within the assembly line grow pod, determine one or more control signals necessary to provide or pressurize the fluid, and provide the one or more control signals to the one or more pumps.

An assembly line grow pod includes a track extending between a growing region and a sanitizing region, a cart movably engaged with the track, a sanitizer system that applies a sanitizer solution to the cart at the sanitizing region, the sanitizer system including a gray solution tank for storing sanitizer solution runoff collected from the sanitizing region, a watering system that provides water to plant matter on the cart at the growing region, the watering system including an untreated water tank for storing water runoff collected from the growing region, and a flowmeter fluidly coupled to at least one of the sanitizer system and the watering system.

A hydrophonic planter for growing plants, comprising one or more growing cups filled with growing bed substrate, one or more dry tubes attached to a bottom side of the growing cup(s) where the dry tube(s) is mechanically coupled to a container containing nutrient solution, one or more water pumps driving a sprinkle of the nutrient solution through water pipes into the growing cup(s), a controller controlling operation of the water pump(s) and a communication component electronically coupled to the controller for communicating with one or more remote devices to transfer data between the controller and the remote device(s). Wherein the sprinkle flows over roots of one or more plants planted in the growing cup(s). A residue of the sprinkle flows through one or more holes located at the bottom side of the growing cup(s) and through the dry tube(s) to be accumulated at the bottom of the dry tube(s).

A method of operating a sapling hydrating system for a planting apparatus. The method comprising determining a release pressure of hydrating fluid for a release valve to hydrate a sapling based on a target distribution rate of the hydrating fluid, wherein the target distribution rate is received via an input signal. The method further comprising controlling a supply pressure of the hydrating fluid from a pump to be greater than or equal to the release pressure, and controlling an unloading valve fluidly disposed between the pump and a hydrating fluid storage tank. The unloading valve regulating a maximum supply pressure. The method further includes controlling the release valve to provide a first portion of the hydraulic fluid to the release valve at an unloading pressure greater than or equal to the release pressure, and directing the remainder of the hydrating fluid back to the storage tank.

System and methods for monitoring the growth of an aquatic plant culture and detecting real-time characteristics associated with the aquatic plant culture aquatic plants. The systems and methods may include a control unit configured to perform an analysis of at least one image of an aquatic plant culture. The analysis may include processing at least one collected image to determine at least one physical characteristic or state of an aquatic plant culture. Systems and methods for distributing aquatic plant cultures are also provided. The distribution systems and methods may track and control the distribution of an aquatic plant culture based on information received from various sources. Systems and methods for growing and harvesting aquatic plants in a controlled and compact environment are also provided. The systems may include a bioreactor having a plurality of vertically stacked modules designed to contain the aquatic plants and a liquid growth medium.

An intelligent farming arrangement comprises a cultivation receptacles receiving a soil medium for cultivation of a plant. Each receptacle has a growth condition sensor for monitoring a condition of the soil medium in the receptacle. A leaching reservoir arranged below the receptacles receives leached nutrients from the receptacles gravity. A fluid redistribution arrangement having at least one fluid pump is arranged within the reservoir for redistributing such nutrients from the reservoir to the receptacles. A controller is in communication with each sensor and the fluid redistribution arrangement, the controller configured to operatively provide a GUI, via a communications network, to a user, the GUI having a prediction engine configured to predict plant growth in each receptacle by analysing the monitored soil condition, the GUI configured to display such predicted plant growth and monitored soil condition and to enable remote control of the fluid redistribution arrangement in real-time.

A wall mounted agricultural assembly includes a first planter and a second planter below the first planter, and a water supply arrangement that includes a fluid supply delivering fluid from a fluid supply to the first and second planters and a first valve configured to allow or prevent fluid flow to the planters, and a second valve configured to prevent or allow fluid to bypass the planters.

First beam source radiates a near infrared reference beam of 905 nm, in which light tends not to be absorbed in water toward a leaf of a plant. Second beam source radiates a near infrared measuring beam of 1550 nm, in which light tends to be absorbed in water toward the leaf of the plant. Threshold level setter/water content index detector calculates a water content index of one leaf as a total sum Ln(I.sub.905/I.sub.1550) of the reflection intensity ratio. Controller displays a graph representing a total sum of water content of the leaf and a pixel average value as a time-transition of the water content contained in the plant from the start of the measurement period on a UI screen of a monitor. Viewed from the first and second beam sources, a white reference substrate covering a back surface of the leaf is disposed on the leaf of the plant.