A driver for a lighting device includes a light emitting diode (LED) driver circuit utilizing interface elements for supporting multiple control connectivity options, the LED driver circuit utilizing a processor having a physical layer interfaces coupled to the interface elements and configured to operatively support a plurality of network protocols, the processor being configured to perform a plurality of functions, including a function of providing a bridge or gateway between network protocols of the plurality of network protocols, the processor being configured to: detect available network protocols of the plurality of network protocols; select, for a physical layer interface, a mode of operation (from modes of operation including, for example: an inactive mode, a monitoring mode, a gateway mode, and a primary mode) appropriate to ensure interoperability and backward compatibility for the available network protocols; and assign one or more of the available network protocols to the physical layer interface(s).

Exemplary embodiments of the present disclosure are directed to a lighting system that includes a line control module and light modules. The line control module can be configured to interrupt power to the light modules according to one or more power interruption schemes to control an operation of the light modules. The line control module can have user interface circuitry including a rotary encoder with a shaft and a push button, a preview circuit, and indicator light emitting diodes. A user can interact with the lighting system via the user interface circuitry, which can be configured to provide visual feedback of various settings of the lighting system.

Systems and methods which utilize luminaires that include wireless communication capabilities that allow the luminaires to be controlled by a wireless-enabled mobile system disposed proximate the luminaires. Control of a network of wireless-enabled luminaires is provided via a single mobile system utilizing wireless communication through at least one gateway luminaire without requiring connection between the luminaires and a central management system (CMS). Information sent to or collected from the luminaires through the mobile system may be transferred via a mobile network interface from or to a CMS. The luminaires may use their wireless communication ability to obtain data from nearby wireless sensors, which data may be collected by the mobile system from luminaires in the network of luminaires when the mobile system is positioned proximate at least one of the luminaires. The sensor data and/or other data may be uploaded to the central management system in a non-real-time period.

A method of controlling illumination, including transmitting location information from a communication device to a computer; receiving illumination data with the communication device, where the illumination data is generated by the computer based at least in part on the location information; and transmitting an illumination signal from the communication device to a wearable accessory containing at least one light source, where the illumination signal is based at least in part on the received illumination data and is operable to actuate the at least one light source.

A mechanism for control and configuration of a lighting system from a user interface. For instance, a wall module designed as a user interface for a tenant to control the system may be implemented so as to be used not only to control the lighting system but also to configure it. The lighting system may involve a controller, circuits of lights, relays, motion and ambient detectors, scenes, schedules, and more. An additional user interface such as a wall module may be connected to the lighting system for control and configuration of the system.

A method (3600) and system (2800, 2900, 3000, 3100) autonomously create a restore point for a luminaire controller (2810, 3110) and restore it to proper operation when required. The luminaire controller operates by using first operating software having a first software image, and receives a second software image of second operating software. The luminaire controller communicates the first software image to a first device (2820, 3120) connected to the luminaire controller via a communication network (2805, 3105), installs the second operating software, and performs a self test of the luminaire controller. If the luminaire controller fails the self test, the luminaire controller requests via the network that the first device transfer the first software image to the luminaire controller via the network, receives the first software image, installs the first operating software, and reverts to operation with the first operating software.

A scalable building control system comprising a plurality of network bridges and plurality of zone control systems each comprising one or more zone control devices and a load controller. Each zone control device is adapted to generate and transmit load control messages over a zone wireless network. The a load controller is adapted to receive the load control messages over the zone wireless network and control an electrically connected load device in response to the load control messages. Each of the plurality of network bridges is adapted to removably couple to at least one load controller of a zone wireless network to connect the zone control system as a node of a centralized wireless network. The network bridge is further adapted to transmit messages between the centralized wireless network and a connected load controller.

A lighting system includes a solid state luminaire configured to be mounted to provide task lighting to at least one area, a user interface configured to accept lighting settings for the lighting system, and a user interface configured to enable at least one of the solid state luminaire and an area light source to be controlled to provide a desired illumination level to a workspace, wherein the solid state luminaire and the area light source both illuminate the workspace.

A method includes receiving a first signal indicating a first movement in first predefined zone at a first time. A first activation signal is communicated to cause a first light source in the first predefined zone to be activated and provide downward illumination in the first predefined zone. A second activation signal is communicated to cause a second light source that in a second predefined zone to be activated and provide downward illumination in the second predefined zone. Responsive to an absence of receiving a second signal indicating a second/return movement in the first predefined zone at or before a second time that is after the first time, an alarm signal is transmitted that is indicative of an occurrence of a potential non-normal event.

Disclosed are examples of lighting devices and other devices that are equipped with a cellular transceiver that is configured to communicate using licensed cellular radio frequency spectrum in both a small-scale cellular network and a large-scale cellular communication network. By utilizing a short-range, low-power cellular transceiver setting, a lighting device facilitates communication, within the space in which the lighting device is installed, of messages between the lighting device and other types of user devices. Such an equipped lighting device may be configured to participate in the generation and delivery of different types of messages, such as data, emergency broadcast information, news and other information as well extend the reach of devices within the space in which the equipped lighting devices are located.