A system to identify incidents associated with streetlight fixtures based on sensor data from one or more smart sensor devices. Each smart sensor device is coupled to a respective streetlight fixture and captures data from one or more sensors. The data from a single smart sensor device or a plurality of smart sensor devices is aggregated to generate a current data signature of the one or more smart sensor devices. The current data signature is compared to a plurality of known signatures to determine if an incident associated with a streetlight fixture has occurred. Such incidents can include a failed light source, a failing light source, a weather incident, a geologic incident, etc. Depending on the type of incident an instruction is sent to the one or more smart sensor devices to perform one or more responsive actions.

An adapter for a greenhouse and indoor grow automated controller is provided. The adapter includes a power input, a power output, a control input, a main controller, and a first control output. The power output is electrically coupled with the power input. The control input is configured to receive an original control signal from an automated greenhouse controller. The main controller is coupled with the power input to facilitate powering of the main controller from the power source. The main controller is in signal communication with the control input and is configured to convert the original control signal from the automated greenhouse controller into an LED-compatible driver signal. The first control output is in signal communication with the main controller. The original control signal conforms to a first signal protocol and the LED-compatible driver signal conforms to a second signal protocol that is different from the first signal protocol.

An adapter for a greenhouse and indoor grow automated controller is provided. The adapter includes a power input, a power output, a control input, a main controller, and a first control output. The power output is electrically coupled with the power input. The control input is configured to receive an original control signal from an automated greenhouse controller. The main controller is coupled with the power input to facilitate powering of the main controller from the power source. The main controller is in signal communication with the control input and is configured to convert the original control signal from the automated greenhouse controller into an LED-compatible driver signal. The first control output is in signal communication with the main controller. The original control signal conforms to a first signal protocol and the LED-compatible driver signal conforms to a second signal protocol that is different from the first signal protocol.

A method of replacing one of a light module and a driver module of a light unit includes reading a VLC code from a data storage memory of one of the light module and the driver. The visible light communication (VLC) code is transferred, via a connection between the light module and the driver module, and stored in the other one of the light module and the driver module. One of the light module and the driver module is elected for replacement. The VLC code from the other one of the light module and the driver module is transferred to the replaced one of the light module and the driver module. The transferred VLC code is stored in the data storage memory of the replaced one of the light module and the driver module.

An emergency lighting device includes a housing, a light emitter positioned in the housing, a control circuit positioned in the housing and operatively connected to the light emitter, an indicator light positioned in the housing, and a fault indicator circuit positioned in the housing and operatively connected to the indicator light. The fault indicator circuit is configured to monitor the light emitter, analyze activation of the light emitter, and activate the indicator light based on the analysis of the activation of the light emitter.

An emergency lighting device includes a housing, a light emitter positioned in the housing, a control circuit positioned in the housing and operatively connected to the light emitter, an indicator light positioned in the housing, and a fault indicator circuit positioned in the housing and operatively connected to the indicator light. The fault indicator circuit is configured to monitor the light emitter, analyze activation of the light emitter, and activate the indicator light based on the analysis of the activation of the light emitter.

Technologies are described for an emergency lighting system and methods of providing emergency light. The emergency lighting system has a luminaire comprising with least one light source and a wireless communicator module in electrical communication with an uninterrupted power supply. The wireless communicator module is configured to detect a power loss in the uninterrupted power supply and send a wireless signal notification of the power loss. The luminaire is configured to receive the wireless signal notification of the power loss and to supply power to the luminaire with a backup power source.

Technologies are described for an emergency lighting system and methods of providing emergency light. The emergency lighting system has a luminaire comprising with least one light source and a wireless communicator module in electrical communication with an uninterrupted power supply. The wireless communicator module is configured to detect a power loss in the uninterrupted power supply and send a wireless signal notification of the power loss. The luminaire is configured to receive the wireless signal notification of the power loss and to supply power to the luminaire with a backup power source.

A method is provided for operating an illuminating device for a vehicle that features means of influencing light or a plurality of light sources for the targeted generation of pixels of a light distribution. In the event of failure of at least one pixel of the light distribution caused by a defect in one section of the means of influencing light or by malfunction of one of the light sources, at least one non-defective section of the means of influencing light or or at least one non-malfunctioning light source is actuated in order to correct the light distribution. The at least one non-defective section of the means of influencing light or at least one of the non-malfunctioning light sources is actuated in such a way that at least one pixel of the light distribution adjacent to the at least one malfunctioning pixel is reduced in its brightness.

An Ethernet lighting control system comprises an ARTNET console and several rows of stage lights, wherein each row of stage lights comprises several stage lights successively connected in series, each stage light being internally provided with a network switching unit. The ARTNET console is connected to a network switching unit of a first stage light in each row of stage lights, by means of a network cable respectively; adjacent stage lights in each row of stage lights are connected in sequence by means of a network cable; a network control signal sent by the ARTNET console is delivered to the network switching unit of the first stage light; and the network switching unit of the preceding stage light receives and delivers the network control signal to an internal circuit of the stage light for processing, and then switches to the network switching unit of the subsequent stage light.