Methods of installing and using a horticulture lighting controller having a substantially rectangular shaped housing with an in-operation removable front cover panel, the methods preferably comprising mounting the fully assembled lighting controller to a mounting surface without first having to remove any component of the controller, remove a front or outer cover of the controller, perform any wiring connections on a backside or backplane of the controller chassis, or pre-wire any connections whatsoever, and then removing the front cover panel to connect the controller to a power supply circuit.

Embodiments described herein provide systems for inducing a desired response in an organism by controlling the duty cycle, wavelength band and frequency of photon bursts to an organism, through the photon modulation of one or more photon pulse trains in conjunction with one or more different photon pulse trains to the organism and duty cycle, where the photon modulation and duty cycle is based upon the specific needs of the organism. Devices for inducing a desired response in an organism such as growth, destruction or repair through the photon modulation of one or more photon pulse trains in conjunction with one or more different photon pulse trains to the organism are also provided. Further provided are methods for the optimization of organism growth, destruction or repair through the use of high frequency modulation of photons of individual color spectrums.

Embodiments described herein provide systems for inducing a desired response in an organism by controlling the duty cycle, wavelength band and frequency of photon bursts to an organism, through the photon modulation of one or more photon pulse trains in conjunction with one or more different photon pulse trains to the organism and duty cycle, where the photon modulation and duty cycle is based upon the specific needs of the organism. Devices for inducing a desired response in an organism such as growth, destruction or repair through the photon modulation of one or more photon pulse trains in conjunction with one or more different photon pulse trains to the organism are also provided. Further provided are methods for the optimization of organism growth, destruction or repair through the use of high frequency modulation of photons of individual color spectrums.

A cover member for an in-store greenhouse is disclosed, with which radiation exiting the in-store greenhouse can be influenced or modified.

A cover member for an in-store greenhouse is disclosed, with which radiation exiting the in-store greenhouse can be influenced or modified.

The present disclosure relates to a module and system for indoor farming. In some embodiments, an indoor farming module includes a container compartment divided into a grow zone and a control zone, wherein a grow zone comprises a chassis with a plurality of horizontal and vertical frame members configured to support a plurality of carts each carrying a tray with a plurality of plants and wherein the control zone includes an air blowing unit integrated so as to direct air between a drop ceiling and a structural ceiling of the indoor farming module and an air conditioning unit configured to condition an atmosphere in the grow zone by producing cool dry air that is blown into a plenum space located between the drop ceiling and a structural ceiling.

The present disclosure relates to a module and system for indoor farming. In some embodiments, an indoor farming module includes a container compartment divided into a grow zone and a control zone, wherein a grow zone comprises a chassis with a plurality of horizontal and vertical frame members configured to support a plurality of carts each carrying a tray with a plurality of plants and wherein the control zone includes an air blowing unit integrated so as to direct air between a drop ceiling and a structural ceiling of the indoor farming module and an air conditioning unit configured to condition an atmosphere in the grow zone by producing cool dry air that is blown into a plenum space located between the drop ceiling and a structural ceiling.

The present invention is a compact plant enclosure intended for use in locations with peripheral space restrictions. The top and one side of the enclosure form a continuous curved face which comprises multiple translucent flexible access panels that can be slid along guide channels incorporated into the sides of the curved frame components on either side of the flexible panels. The guide channels and flexible panel edges may incorporate retention features that limit the lateral movement of the flexible access panels. The opposing wall may be comprised of a single fixed translucent vertical panel or multiple vertical access panels. The remaining two vertical sides of the plant enclosure each comprise a fixed, translucent rigid panel. In another embodiment of the present invention, multiple distinct intermediate segments of the enclosure are defined by interstitial curved and vertical frame components supporting adjacent sets of flexible access and opposing vertical panels.

A cover member for an in-store greenhouse is disclosed, with which radiation exiting the in-store greenhouse can be influenced or modified, so that outgoing total radiation has a white color on the Planck curve.

A cover member for an in-store greenhouse is disclosed, with which radiation exiting the in-store greenhouse can be influenced or modified, so that outgoing total radiation has a white color on the Planck curve.