Power receptacle control circuitry includes load switching circuitry, communications circuitry, sensor circuitry, processing circuitry, and a memory. The sensor circuitry includes a light sensor. The processing circuitry is coupled to the load switching circuitry, the communications circuitry, the sensor circuitry, and the memory. The memory includes instructions, which, when executed by the processing circuitry cause the power receptacle control circuitry to selectively deliver power to a load via the load switching circuitry, detect a modulated light signal via the light sensor, and join a group of devices based on the modulated light signal.

Sectorized Visual Light Communication (VLC)/Dark Light Communication (DLC) systems and sensors are generally disclosed. The exemplary VLC/DLC systems may include a transmitter for transmitting a light signal including information about the transmitting light source, and a receiver with a number of surface facets facing in different directions at different angles, and configured to determine a distance and a direction of a transmitting light source from the VLC/DLC receiver. Associated exemplary methods for automatic identification and grouping of light sources are disclosed.

A linear lighting fixture may comprise lighting control devices for controlling lighting loads in a load control system. Each linear lighting fixture may include a fixture controller configured to control lighting control devices. The fixture controller may receive messages from one or more devices in the load control system for controlling lighting control devices in the linear lighting fixture. The fixture controller may receive the message and communicate with the lighting control devices on a wired power/communication link. Each linear lighting fixture may comprise one or more sensors. The sensors may be coupled to the fixture controller to send/receive messages on a wired power/communication link and/or a wireless communication link. The lighting control devices in the fixtures may be zoned separately or together. Each of the sensors in a linear lighting fixture may be zoned with one or more of the lighting control devices in the linear lighting fixture.

Wireless lighting control systems and methods for controlling the illumination of one or more light fixtures are disclosed. Embodiments include a server connected to a wide area network and having software for configuring, monitoring, and controlling lighting fixtures at a site. The control system also includes a wireless gateway at the site communicating with the server via cellular. Wireless devices communicate with the wireless gateway via a mesh network and each wireless device is wired to control at least one lighting fixture. A user interface can connect to the wide area network and enable a user to access server control software. Control instructions entered on the server by the user interface are communicated from the server to the wireless gateway and to the wireless devices. A user site device may be connected to the site mesh network enabling a user to configure, monitor, and control lighting fixtures at the site.

A lighting system utilizes intelligent system elements, such as lighting devices, user interfaces for lighting control or the like and possibly sensors. The system also has a data communication network. Some number of the intelligent lighting system elements, including at least two of the lighting devices, also support wireless communication with other non-lighting-system devices at the premises. Each such element has a communication interface system configured to provide a relatively short range, low power wireless data communication link for use by other non-lighting-system devices at the premises in proximity to the respective intelligent system element. Also, in such an element, the processor is configured to control communications via the communication interface system so as to provide access to the data network and through the data network to the wide area network outside the premises for non-lighting related communications of the other non-lighting-system devices.

A lighting system utilizes intelligent system elements, such as lighting devices, user interfaces for lighting control or the like and possibly sensors. The system also has a data communication network. Some number of the intelligent lighting system elements, including at least two of the lighting devices, also support wireless communication with non-lighting-system devices at the premises. Each such element has a communication interface system configured to provide a short range, low power wireless data communication link for use by non-lighting-system devices at the premises in proximity to the respective intelligent system element. Also, in such an element, the processor is configured to control communications via the communication interface system so as to provide access to the data network and through the data network to the wide area network outside the premises for non-lighting related communications of the non-lighting-system devices.

Networked intelligent lighting devices may utilize visual light communication to perform autonomous neighbor discovery, for example, as part of a map generation process. Individually, each intelligent lighting device within an installation transmits a series of packets via visual light communication for receipt by one or more of the other intelligent lighting devices. Receiving intelligent lighting devices record the number of received packets from each transmitter. Records of numbers of received packets are conveyed via a data communication network to a centralized process. The centralized process utilizes the conveyed records to determine neighbor relationships between lighting devices, for example to generate a map of devices as located within the installation.

A power line communication system and method permit auto-commissioning of multiple device control modules on a DC power line during the power up of the system. Device control modules associated with the peripheral devices are powered up sequentially and a unique address is assigned to each device controller when it is powered up. The device control modules have a unique circuit configuration that allows the use of inexpensive and mostly passive components. The cost effectiveness of the device controller design becomes particularly significant in applications, such as multi-panel OLED lighting fixtures, with high node counts.

An advanced lighting control system including systems for commissioning a network of lighting fixtures preferably includes a plurality of lighting fixtures, each having a sensor and control module. The sensor and control module includes occupancy and light sensing elements, and a first transceiver. The lighting fixtures can send wireless signals to a second transceiver located in a room controller and/or a network coordinator. The room controller being configured to interpret the occupancy and light sensing information and make decisions thereon, while the network coordinator can rank the lighting fixtures according to a determined signal strength. The network coordinator can command each of the lighting fixtures to illuminate, and based on an observation of the lighting fixture, a determination is made about whether the lighting fixture is located in a particular room. The network coordinator can also include a third transceiver for receiving wireless commands from a remote device.

Embodiments of the present disclosure decrease conflicts between individual lighting devices in a wireless network when responding to a broadcast/multicast message sent to a group of devices. In some embodiments the devices delay sending their acknowledgment to commands until after a specific time period. Some embodiments limit the number of time delays to one of a predetermined number of time delays, where the number of time delays are assigned by an external source, such as the gateway. Still other embodiments include assigning each device one of a limited number of preset time delays, where the total number of preset time delays are less than the number of devices, for example, ten (10) percent of the number of devices (here some devices will have the same time delays as other devices). Still other embodiments use bitmaps to designating which one or more individual devices the message is intended for.