The commissioning of a smart building technology system is implemented with the use of a binding table in a relational database to bind one or more sections of virtual devices representing, e.g., lights, sensors, actuators and room controls, to the network addresses of physical devices. Plans for redundant sections in large building are created in terms of virtual devices and logical functions (such as programmed groups of devices, scenes and recipes) without direct binding to physical devices. Software creates reference copies of the plan for redundant sections the building, through use of a binding table, and attaches the reference copy to the location of the respective section on a master layout of the building. The plan modeled with virtual devices can be edited or reprogrammed across all reference copies, even after binding to physical devices and commissioning is completed.

A load control system may include control devices for controlling power provided to an electrical load. The control devices may include a control-source device and a control-target device. The control-target device may control the power provided to the electrical load based on digital messages received from the control-source device. The control devices may include a load control discovery device capable of sending discovery messages configured to discover control devices within a location. The discovered control devices may be organized by signal strength and may be provided to a network device to enable association of the discovered control devices within a location. The discovery messages may be transmitted within an established discovery range. The discovery range may be adjusted to discover different control devices. Different control devices may be identified as the load control discovery device for discovering different control devices.

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.

A pairing method for determining communication partners among luminaires and wireless interface (IF) devices, including: generating provisional pairing data by assigning provisional addresses to the luminaires and the wireless IF devices indicated on the layout map and by associating the provisional addresses assigned to the wireless IF devices with the provisional addresses assigned to the luminaires in a one-to-many relationship; in a hardware installation phase in which the luminaires and the wireless IF devices are installed in accordance with the layout map, generating final pairing data by associating the provisional addresses in the provisional pairing data with pre-assigned actual addresses; and notifying the luminaires and the wireless IF devices of each of the actual addresses each is associated with in the final pairing data, and causing the luminaires and the wireless IF devices to store, as an actual address of a communication partner, each of the notified actual addresses.

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.

The invention describes a method of performing automatic commissioning of a network (N) comprising a plurality of network devices (10, 11, 12, 13), wherein each device (10, 11, 12, 13) is characterized by a device identifier (14) and wherein the devices (10, 11, 12, 13) are realized to exchange data packets (2), which method comprises the steps of obtaining a computer-readable installation plan (3) for the network (N), which installation plan (3) comprises a physical location descriptor (31) for devices (10, 11, 12, 13) of the network (N); deducing the network topology (T) of the network (N) from network descriptive information (40, 41, 42, 43) provided by the devices (10, 11, 12, 13) on the basis of data packets (2) exchanged between the devices (10, 11, 12, 13); and comparing the deduced network topology (T) to the installation plan (3) to allocate a physical location descriptor (31) to a device identifier (11). The invention further describes a commissioning system (1) for automatically commissioning a network (N) comprising a plurality of network devices (10, 11, 12, 13), wherein each device (10, 11, 12, 13) is characterized by a device identifier (14) and wherein each device (10, 11, 12, 13) is realized to transmit and receive data packets (2), which commissioning system (5) comprises a source (50) of a computer-readable installation plan (3) for the network (N), which installation plan (3) comprises a physical location descriptor (31) for each device (10, 11, 12, 13) of the network (N); a device control interface (55) realized to collect network descriptive information (40, 41, 42, 43) provided by the devices (10, 11, 12, 13); a topology discovery unit (53) realized to derive the network topology (T) of the network (N) from the provided network descriptive information (40, 41, 42, 43); and a commissioning unit (54) realized to compare the derived network topology (T) to the installation plan (3) to allocate a physical location descriptor (31) to a device identifier (14).

An operation terminal in a lighting system includes: a storage which stores identification information of each of the plurality of lighting controllers; a communication circuit which performs wireless communication with the plurality of lighting controllers; and a terminal controller which transmits schedule information for each of the plurality of lighting devices to the plurality of lighting controllers via the communication circuit. The terminal controller obtains the identification information of a current lighting controller currently connected to the operation terminal from the current lighting controller via the communication circuit. The terminal controller then confirms, based on the identification information, that the identification information of the current lighting controller is identical to the identification information of the target lighting controller to which the schedule information for a target lighting device is to be transmitted, and then transmits the schedule information for the target lighting device to the current lighting controller.

Provided is a lighting apparatus including a memory configured to store wireless network information of the lighting apparatus, a detection circuit configured to detect an alternating current signal supplied to the lighting apparatus, and a processor configured to initialize wireless network information of the lighting apparatus, based on the detected alternating current signal.

A method for commissioning a wireless lighting control system for network connectivity does not require special device network configuration steps during manufacturing. Network configuration happens dynamically and automatically during commissioning of a lighting control group. The method includes receiving at a mobile device an advertisement packet from each of a plurality of lighting control devices via a commissioning network. A commissioning network connection is established with each of the lighting control devices and the mobile device. A lighting control group network table listing an entry for each of the lighting control devices is built to establish the lighting control group that communicates over a lighting control network. The lighting control group network table is sent to a last lighting control device configured by the mobile device via the commissioning network. Receipt of the lighting control group network table readies the device to receive lighting control event messages for the group.

A system for locating an asset can include a first light fixture disposed in a volume of space and having a first transceiver, a first light source, and a first modulation circuit, where the first light source emits a first light output that defines a first line of sight, where the first modulation circuit generates and sends a first VLC signal that is part of the first light output, where a first light fixture location of the first light fixture in the volume of space is previously determined using the first transceiver during an auto-commissioning process. The system can also include a communication device associated with the asset, where the asset is disposed in the volume of space, where the communication device includes a second transceiver, where the second transceiver receives the first VLC signal from the first transceiver.