Plants are optimally grown under artificial narrowband Photosynthetically Active Radiation (“PAR”) of multiple colors, and color palettes, applied in but partially time-overlapping cycles. As well as a long, growing season, cycle, the colored lights are cyclically applied on a short, diurnal, cycle that often roughly simulates a peak-season sunny day at the earth latitude native to the plant. Bluer lights are applied commencing before redder lights, and are likewise terminated before the redder lights. Infrared light in particular, is preferably first applied at a time corresponding to early afternoon, and is temporally extended past a time corresponding to sunset. The colored lights and light palettes preferably rise to, and fall from, different peak intensities over periods from 10 minutes to 2 hours, and relative peak intensities of even such different colors as are used at all vary up to times two (×2) in response to differing PAR requirements of different plants. Computer-controlled colored LED lights realize all.

The present disclosure provides an intelligent lighting control system for automated lighting adjustments. The system includes a lighting control module configured to cause a transmission of a quantity of electrical energy to a lighting circuit and a detector circuit positioned in the lighting control module and configured to detect a change in a strength of detected signal, such as wireless signal. The system includes a controller coupled to the detector circuit and the lighting control module. The controller includes a processor configured to determine a time of day and to cause the lighting control module to change the quantity of electrical energy transmitted to the lighting circuit in response to the time of day exceeding a predetermined time threshold and the change in the strength of the wireless signal falling below a predetermined value. The controller can cause the lighting control module to reduce the quantity of electrical energy.

The present disclosure provides an intelligent lighting control system configured for customization based user detection. A lighting control system includes a module housing, a graphical user interface, and a switch control circuit including a processor configured to modulate the flow of electrical energy to a lighting circuit via a dimmer circuit to produce a plurality of lighting scenes. The processor is configured to identify a proximate device identification, compare the identified device with one or more registered devices saved in a dataset, select a user profile, if the identified device corresponds to one of the one or more registered devices saved in the dataset. The processor is configured to cause a change in at least one of a scene selection protocol for selecting at least one lighting scene from the plurality of lighting scenes based on the user profile selected and a display setting of the graphical user interface.

The present disclosure provides an intelligent lighting control system configured for automated lighting adjustments. A light control module of the lighting control system receives a signal, such as an alarm signal, from an electronic device, such as a mobile electronic device. The light control module is configured to cause a transmission of a quantity of electrical energy to a lighting circuit of a light fixture electrically connected to the lighting control module. The light control module causes a quantity of electrical energy to be transmitted to a lighting circuit at a particular time of day determined based on the alarm signal.

The present disclosure provides an intelligent lighting control system include a pre-mount chassis system. The methods include attaching a chassis to an electrical wall box, the chassis comprising at least one hook extending in an upward direction and at least one opening, the at least one hook positioned along a peripheral portion of the at least one opening. The methods include hanging a base module from the at least one hook in the chassis.

Typical prior art circuits for ignition and operation of UV lamps do not optimize power usage through the whole cycle of ignition and ongoing operation. Typically, the higher power required to initially ignite the UV lamp is not diminished once the UV lamp is burning brightly and at a desired temperature. The circuit of the present invention utilizes a sensor to monitor the light emitted from the UV lamp and a sensor to measure the temperature of the device containing the UV lamp as voltage is applied to it. Once the constant light and desired temperature are achieved, the voltage boost converter is latched away and constant lower voltage is provided to the UV lamp from that point forward, thus optimizing the energy consumption or the energy used for a battery powered device incorporating a UV lamp.

A system and method for a remote state following device that includes an electronic device with a controllable operating state; an imaging device; and control system that when targeted at a control interface interprets a visual state from the control interface, and modifies the operating state in coordination with the visual state.

The present disclosure provides an intelligent lighting control system for automated lighting adjustments. The system includes a first light control module configured to cause a transmission of a first quantity of electrical energy to a first lighting circuit of a first light fixture electrically connected to the first lighting control module. The system transmits a control message from the first light control module to at least one second light control module configured to cause a transmission of a second quantity of electrical energy to at least one second lighting circuit of at least one second light fixture electrically connected to the at least one second lighting control module. The system changes a flow of electricity from the at least one second light control module to the at least one second lighting circuit based on the input received via the first light control module.

A method including receiving information indicative of a first light preference profile, receiving information indicative of a second light preference profile, determining that the first light preference profile differs from the second light preference profile, determining a first light control setting based on the first light preference profile, determining a second light control setting based on the second light preference profile, determining a periodic light source actuation directive, causing sending of the periodic light source actuation directive to the light source, determining a first shutter control directive for the first near eye apparatus, causing sending of the first shutter control directive to the first near eye apparatus, determining a second shutter control directive for the second near eye apparatus, and causing sending of the second shutter control directive to the second near eye apparatus is disclosed.

In accordance with various embodiments of the disclosed subject matter, a lighting control method, a related lighting apparatus and system are provided. One embodiment of the present disclosure provides a lighting control method. The method includes detecting a connection status of a wireless network component of a lighting apparatus and controlling a working status of an illumination component of the lighting apparatus based on the connection status.