Systems, methods and computer-readable media are described herein for commissioning a group of two or more lighting units (102) as a group. In various embodiments, the group may be commissioned based at least in part on the two or more lighting units emitting light having corresponding properties. Additionally or alternatively, in various embodiments, the group may be commissioned based on the two or more lighting units being influenced by sensor events raised by two or more sensors (110) within a predetermined time interval. The two or more sensors may take a variety of forms, including but not limited to a presence sensor, an accelerometer, a sensor configured to detect a signal from a third party network service, and so forth.

Systems and methods are disclosed for generating a backup of configuration information files at a system controller and storing this backup at a server via the use of a network device.

A remote controller comprises a wireless communication interface and a processing unit. The wireless communication interface is communicatively connected with another remote controller. The processing unit is electrically connected with the wireless communication interface. The processing unit generates a first identification code and a second identification code and transmits the first identification code and the second identification code to the another remote controller through the wireless communication interface. The another remote controller transmits the first identification code and the second identification code to a controlled device to establish an indirect pairing relationship between the remote controller and the controlled device and a direct pairing relationship between the another remote controller and the controlled device. A pairing method of remote controllers is also disclosed.

A method of controlling lighting that includes color coding at least one group icon for a scene for lighting on a light control interface. The at least one group icon can be color coded with a first type color coded identifier corresponding to the scene. The method can continue with grouping at least one member icon designating a light function form for at least one lamp to the at least one group icon on the light control interface. The at least one member icon may include a second type color identifier, in which a member icon being grouped to a group icon has a same color for the second type color identifier for the member icon as the first type color identifier for the group icon.

A lighting system includes: a wireless communication device that transmits a test signal; luminaires that measure a signal strength of the test signal upon receipt and transmit signal strength information on the signal strength to the wireless communication device; and a determining unit that determines a condition of the lighting system based on the signal strength or the signal strength information. The determining unit: determines the condition of the lighting system to be acceptable upon confirming transmission of the signal strength information by all luminaires and unacceptable upon failing to confirm transmission of the signal strength information by at least one luminaire; or determines the condition of the lighting system to be acceptable when each signal strength measured by all luminaires exceeds a reference value and unacceptable when the signal strength measured by at least one luminaire is less than or equal to the reference value.

A commissioning system and method that applies a design configuration, representative of a building automation and control system, to a mesh network of network-capable devices. A cloud-based server system works in concert with an installing device, such as a smartphone or tablet, to apply the relevant configuration of scenarios and spaces, as defined in the design configuration during a design phase, to each mesh node in the mesh network. The commissioning system first transforms the defined scenarios and spaces, which essentially represent a logical configuration of the building automation and control system, into a network-centric configuration. Then, the system decomposes the network-centric configuration into a physical configuration of each mesh node, resulting in a set of parameters for each mesh node. The commissioning system then transmits the set of parameters, including one or more group addresses, to the applicable mesh node, for each affected mesh node in the network

Wireless lighting control systems and methods for controlling the illumination of one or more light fixtures are disclosed, including power loss detection of hardware. Embodiments include a zero-cross detection circuit including a timer, the timer reset by a zero-cross detection, and the zero-cross detection circuit detecting a loss of power of the AC supply upon the timer reaching a preset time without resetting. Embodiments further include a first voltage regulator having an input coupled to the AC supply and an output providing a first DC supply. Embodiments still further include a wireless transmitter having a power input, the wireless transmitter for communicating with at least one other component of the wireless device control system. The first capacitor provides energy storage sufficient to power the wireless transmitter for a duration long enough to transmit one message upon detecting the loss of power of the AC supply.

A method of automatically commissioning a lighting system comprising a plurality of luminaires for illuminating one or more regions within a space. The method comprises: receiving signals from a positioning system, indicating a respective location within the space at which each of a plurality of physical entities is detected by the positioning system, each of the entities being a person or a movable nonhuman object. The method further comprises determining a spatial distribution of at least some of the entities based on the locations indicated by the signals from the positioning system, and determining a region within the space corresponding to this spatial distribution. The method then comprises identifying a group of the luminaires that are arranged to illuminate the determined region and storing identifiers of those luminaires together as a group in a commissioning database.

A load control system may include one or more wireless control devices that may be associated via a programming device. An identifier for a first wireless control device may be determined in response to an actuation of a button on the first wireless control device. An association between the first wireless control device and a second wireless control device may be defined at the programming device. The identifier for the first wireless control device may be transmitted to the second wireless control device, which may cause the first wireless control device to enter a sleep mode. The first wireless control device may enter the sleep mode after an actuation of a button on the first wireless control device. The identifier may be determined in response to the actuation of the button on the first wireless control device and/or prior to the first wireless control device entering the sleep mode.

A smart lighting device may be configured to be controlled in response to control instructions in messages and/or phase-control signals. The smart lighting device may determine whether to respond to the phase-control signal or the control instructions in messages. The smart lighting device may be configured to recognize whether it is electrically connected to a smart load control device or a non-smart load control device. A load control device may determine whether it is electrically connected to a mixed circuit or a non-mixed circuit. When the load control device determines that the circuit is a mixed circuit, the load control device may transmit phase-control signals and control instructions in messages at the same time. The load control device may determine that a smart lighting device has been added (e.g., electrically connected) to the circuit it is electrically connected to.