Embodiments of the present invention provide hydroponics farming apparatus, and systems including the same. The farming apparatus comprises a frame, a plurality of functional systems, a first plurality of sensors configured to monitor conditions associated with farming of the one or more plants, and one or more modular storage cabinets removably attached to the frame. The one or more modular storages include electronics that are pre-assembled and configured to communicate with one or more of the first plurality of sensors and the plurality of functional systems. The electronics includes a main controller configured to collect data from the first plurality of sensors.

An annular LED grow light is disclosed, which comprises a radiator, a light source board, and a power supply box. The light source board is composed of a PCB light board and a plurality of LED lamp beads, wherein the LED lamp beads are arranged on the PCB light board in an annular array about a center. The beneficial effects of the present disclosure are: the photosynthetic photon flux density (PPFD) is distributed more evenly after the LED lamp beads are arranged in an annular array about the center, thus the effective irradiated area is larger, and the cost has been saved.

A greenhouse has a daylighting member supported by a frame. The daylighting member partitions a growing space for agricultural products from an outside world, and emits light, which has entered from a light incident surface on one side, from a light emitting surface on the other side. The daylighting member has a transparent substrate layer and a transparent light emitting layer provided closer to a light emitting surface side than the substrate layer. The light emitting layer has a refractive index of 1.54 or less, water absorbability, and an equilibrium moisture content of 10% or greater at 25° C. and a relative humidity of 80%.

A cohesive and independent hydroponic system is provided having a water tank base supporting a hollow tower for housing plants for vertical farming. The hydroponic system has a central water control system position inside the water tank base and/or the hollow of the hollow tower for centralized control and easy of scalability.

The present techniques concern methods and systems for controlling horticultural light sources illuminating a plant or crop during a distribution process including one or more phases, and more specifically relate to methods and systems for controlling horticultural lighting sources during an initial phase, a transit phase and a selling phase of the distribution process, each phase taking place a different location one from another. In some implementations, the present techniques allow illuminating the plant or crop according to a global dynamic lighting scenario, wherein at least a portion of the global dynamic lighting scenario is associated with a corresponding phase of the distribution process.

A fluid-cooled LED-based lighting fixture for Controlled Environment Agriculture (CEA) to improve energy efficiency, recycle waste heat, and support the operation of environmental sensors in a controlled agricultural environment. In one example, a lighting fixture frame mechanically supports and houses respective components of the lighting fixture and includes a light spine to mechanically couple the lighting fixture to a support structure. One or more coolant pipes formed from copper and coupled to the lighting fixture frame conduct a fluid coolant through the lighting fixture to remove heat. The lighting fixture comprises one or more LED modules to emit light, one or more onboard sensors and/or cameras, wireless communication functionality, and multiple electrical power and communication ports to facilitate interconnection of the lighting fixture in a variety of controlled agricultural environments. In some examples, the lighting fixture includes a multispectral imaging system to acquire multispectral images of the environment.

The present disclosure relates to different techniques of controlling an agricultural system, as for example a controlled agricultural system, an agricultural light fixture and a method for agricultural management. Furthermore, the disclosure relates to an agricultural system, which comprises a plurality of processing lines for growing plants of a given plant type, wherein a first processing line in the plurality of processing lines is configured to move a first plurality of plants through the agricultural system along a route; and apply a first growth condition to the first plurality of plants to satisfy a first active agent parameter for the first plurality of plants.

A growing system is described where plants are grown in containers and the containers are stored in stacks. Above the stacks runs a grid network of tracks on which load handling devices run. The load handling devices take containers from the stacks and deposit then at alternative locations in the stacks or deposit them at stations where goods may be picked out. The containers may be provided with one or more of the following services: power, power control, heating, lighting, cooling, sensing means, data logging means, growing means, water and nutrients.

The present disclosure relates to an LED lighting device for strawberry seedling raising.

The LED lighting device for strawberry seedling raising according to an exemplary embodiment of the present disclosure includes: a light emitting unit composed of a first light emitting part composed of a red region wavelength emission LED and a blue region wavelength emission LED and a second light emitting part composed of the red region wavelength emission LED and an infrared region wavelength emission LED; and a control part for controlling the light emitting unit to manage a strawberry seedling raising, and controlling each LED included in the first light emitting part or the second light emitting part to be turned on/off based on a preset seedling raising mode.

Embodiments include a control apparatus, a control method, and a control system that can effectively utilize an index regarding light incident on a measured object by obtaining the index effective for the measured object. The control apparatus can effectively utilize an effective index by controlling improvement of an environment that affects calculation of the effective index on the basis of the effective index representing an index that is related to light incident on a measured object and that is effectively utilized for the measured object. The measured object may be a plant.