A method of providing light to plants. The method comprises providing a plurality of plants within a room, grouping each plant of the plurality of plants into one of a plurality of groups of plants based at least in part on a desired total light integral (“TLI”) for each of the plurality of plants and providing the corresponding desired TLI to each plant of the plurality of plants by sequentially providing light to each of the plurality of groups of plants during a time period. For each group of plants, each plant has a substantially similar photoperiod and a sum of the photosynthetic photon flux densities (“PPFDs”) of all plants in the group of plants is substantially similar.

An indoor gardening appliance includes a grow module rotatably mounted within a liner to at least partially define a first grow chamber and a second grow chamber. A climate control system includes an evaporator plenum housing an evaporator, a fan assembly for urging air through the evaporator plenum, recirculation ducts for independently circulating air through the first grow chamber and the second grow chamber, and ambient duct systems for independently circulating fresh ambient air through the first grow chamber and the second grow chamber. A system of dampers selectively opens or closes each respective recirculation duct and ambient duct system for independent climate control of the first grow chamber and the second grow chamber.

An indoor gardening appliance includes a grow module rotatably mounted within a liner to at least partially define a first grow chamber and a second grow chamber. A climate control system includes an evaporator plenum housing an evaporator, a fan assembly for urging air through the evaporator plenum, recirculation ducts for independently circulating air through the first grow chamber and the second grow chamber, and ambient duct systems for independently circulating fresh ambient air through the first grow chamber and the second grow chamber. A system of dampers selectively opens or closes each respective recirculation duct and ambient duct system for independent climate control of the first grow chamber and the second grow chamber.

To provide a mechanism for performing environment control in a plant cultivation device and process control regarding to a work process for cultivating a plant. A plant cultivation device includes a plurality of sensors for monitoring a growing condition of a plant to be cultivated; an environment controlling unit for controlling an environment which is a condition of at least one of light, air, water, and space in the plant cultivation device; and a process controlling unit for controlling a work process for cultivating the plant.

A vegetation wall system includes an irrigation tank, a vegetation mounting unit with a vegetation holding unit, a pump feeding water from the tank to the holding unit, a programmable logic control unit including a central processing unit and a sensor, wherein the central processing unit monitors an aspect in the wall system by measuring, by the sensor, a component of the aspect as a first component measurement, waiting a predetermined period of time and then measuring, by the sensor, the component of the aspect as a second component measurement, determining, by the central processing unit, a change in the aspect based on the first and second measurements and the predetermined period of time, determining whether the change is outside a threshold range, in response to determining that the change is outside the threshold range, determining that an anomalous condition exists, and generating an alert when the anomalous condition exists.

A vegetation wall system includes an irrigation tank, a vegetation mounting unit with a vegetation holding unit, a pump feeding water from the tank to the holding unit, a programmable logic control unit including a central processing unit and a sensor, wherein the central processing unit monitors an aspect in the wall system by measuring, by the sensor, a component of the aspect as a first component measurement, waiting a predetermined period of time and then measuring, by the sensor, the component of the aspect as a second component measurement, determining, by the central processing unit, a change in the aspect based on the first and second measurements and the predetermined period of time, determining whether the change is outside a threshold range, in response to determining that the change is outside the threshold range, determining that an anomalous condition exists, and generating an alert when the anomalous condition exists.

Activation of a far-red light device with a far-red light frequency that includes moonlight light that promotes the conversion of inactive Pfr to active Pr in short-day plants prior to a dark period.

Facility layouts and configurations for an automated crop production system for controlled environment agriculture. In particular implementations, the core of the facility comprises a controlled growth environment and a central processing system. The controlled growth environment includes systems for exposing crops housed in modules, such as grow towers, to controlled environmental conditions. The central processing system may include various stations and functionality both for preparing crop-bearing modules to be inserted in the controlled growth environment for harvesting crops from the crop-bearing modules after they have been extracted from the controlled growth environment, and for cleaning or washing crop-hearing modules for re-use. The remaining aspects of the crop production facility—such as seeding stations, propagation facilities, packaging stations and storage facilities—are arranged to achieve one or more desired efficiencies relating to capital expenditures or operating costs associated with an automated crop production facility.

A translucent solar module assembly for integration with a greenhouse having a frame with a plurality of roof supports includes a pair of brackets attachable to each of the plurality of roof supports, a bi-facial solar panel attachable to the pair of brackets, and a pair of reflector rails attachable to each of the plurality of roof supports. A dichroic reflector is attachable to the pair of reflector rails.

The invention relates to the field of soil and ionitoponic (ionitoponics) automated cultivation of plants having various morphological structures and can be applied in everyday life. The technical result to be achieved by the invention is to ensure a balanced growth and development of plants without human intervention. The essence of the invention is that a plant cultivation device comprises a plant cultivation chamber and the following controller-operated modules: a lighting module, a ventilation module, a substrate humidity monitoring module, an irrigation module, a module for monitoring a water level in a reservoir, and a plant growth stage monitoring module. The device further comprises: a controller-operated plant cultivation module comprising a container and a substrate provided with all necessary micro—, macroelements and microorganisms to achieve the best plant growth; a substrate humidity monitoring module; and a means for differentiating air flows.