Plant cultivation for increasing the phytochemical content of a Labiatae plant is provided. The plant cultivation includes cultivating the Labiatae plant in a visible light environment having a dark period and a light period during which the Labiatae plant is exposed to visible light in an alternate manner, and performing treatment with UVB radiation during the light period for at least one day before harvesting. A cumulative dose of the UVB radiation may range from 0.54 J/m.sup.2 to 4.32 kJ/m.sup.2.

Disclosed are a system and method for managing a smart farm using a self-contained hydrogen power system. A system for managing a smart farm includes a self-contained hydrogen generation unit configured to purify intake-water, generate clean hydrogen through water electrolysis, generate energy through a fuel cell by using the generated clean hydrogen, and store the energy; and a growing condition control unit configured to receive, from the self-contained hydrogen generation unit, energy for driving a plurality of sensors and a camera and control an environment for growing agricultural produce.

A plant growth monitoring system comprises an image capture system for capturing images over time of a plant being monitored. The images are used to derive successive time instants corresponding to predetermined growth states of the plant. A temperature exposure parameter is obtained between the successive time instants, based on a monitored temperature vs. time function. Information relating to a plant health is derived from the temperature exposure parameter.

A greenhouse-linked air conditioning system includes a first greenhouse through which sunlight is transmitted and in which plants are grown, a second greenhouse through which sunlight is not transmitted and in which plants are grown, an indoor space excluding the first and second greenhouses in a building, a sunlight panel formed outside the first greenhouse and generating power using the sunlight, an auxiliary light source connected to the sunlight panel to provide light to the second greenhouse, and an air conditioning unit configured to connect the first and second greenhouses and the indoor space and selectively exchange air, humidity, and energy between the first and second greenhouses and the indoor space.

The invention is an autonomous wall garden system containing removeable trays, a water delivery system, a tray water level sensor system, and optional grow lights and user interface. The present invention provides a vertical plant growing environment that can be configured to monitor and, in certain cases automatically provide, the appropriate light, temperature, humidity and water for the specific plants in the garden.

A lighting arrangement (1) for use in a plant growing environment comprises a light source (5). The plant growing environment comprises at least a first plant container (11) and a second plant container (12) adapted to move relative to each other. The light source is arranged to illuminate a plant from below when the plant is provided in the first plant container. An angle of the illumination depends on a distance between the first plant container and the second plant container.

Systems, methods and computer-readable media are provided for entering a fail safe mode for a controlled agricultural environment (CAE). The CAE includes movable receptacle supports for holding plants. In response to determining a fault condition in the CAE or in environmental conditioning equipment for the CAE, operation of the CAE or the environmental conditioning equipment is controlled to effect a change from a standard operating mode to a fail safe mode. The standard operating mode corresponds to desired environmental conditions in the CAE and the fail safe mode corresponds to non-ideal environmental conditions.

Systems, methods and computer-readable media are provided for entering a fail safe mode for a controlled agricultural environment (CAE). The CAE includes movable receptacle supports for holding plants. In response to determining a fault condition in the CAE or in environmental conditioning equipment for the CAE, operation of the CAE or the environmental conditioning equipment is controlled to effect a change from a standard operating mode to a fail safe mode. The standard operating mode corresponds to desired environmental conditions in the CAE and the fail safe mode corresponds to non-ideal environmental conditions.

An apparatus for cultivating plants according to an embodiment of the present disclosure includes a cabinet including an outer case forming an outer appearance, an inner case forming a cultivation space, and an insulating material disposed in a space between the inner case and the outer case; an evaporator provided inside the cultivation space to adjust a temperature of the cultivation space; a door configured to open and close the cultivation space; a cultivation shelf configured to be disposed inside the cultivation space, on which a seed package containing plants for cultivation is seated; a water supply module configured to supply water to the cultivation shelf; a machine room having a separate space formed under the cultivation space; a compressor configured to be disposed in the machine room and to be connected to the evaporator to compress the refrigerant; a heat dissipation fan configured to be disposed in the machine room and configured to dissipate heat generated by the compressor to the outside; a suction duct formed to pass through the insulating material from the upper portion of the cabinet and through which outside air flows therein; and a discharge duct formed to pass through the insulating material from a lower surface of the cabinet to discharge air inside the cultivation space to the machine room.

An apparatus for cultivating plants according to an embodiment of the present disclosure includes a cabinet including an outer case forming an outer appearance, an inner case forming a cultivation space, and an insulating material disposed in a space between the inner case and the outer case; an evaporator provided inside the cultivation space to adjust a temperature of the cultivation space; a door configured to open and close the cultivation space; a cultivation shelf configured to be disposed inside the cultivation space, on which a seed package containing plants for cultivation is seated; a water supply module configured to supply water to the cultivation shelf; a machine room having a separate space formed under the cultivation space; a compressor configured to be disposed in the machine room and to be connected to the evaporator to compress the refrigerant; a heat dissipation fan configured to be disposed in the machine room and configured to dissipate heat generated by the compressor to the outside; a suction duct formed to pass through the insulating material from the upper portion of the cabinet and through which outside air flows therein; and a discharge duct formed to pass through the insulating material from a lower surface of the cabinet to discharge air inside the cultivation space to the machine room.