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 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.

The present disclosure provides an intelligent lighting control system. The lighting control system includes a base module including a base housing forming a well and including a first electrical connector positioned in the well. A depressible switch is housed in the well that includes a spring biasing the depressible switch into an extended position that opens an electrical circuit between the power terminal and the first electrical connector. The lighting control system also includes a light switch module configured for nesting, at least in part, in the well of the base module. The light switch module includes a module housing configured to press the depressible switch into a retracted position upon nesting in the well and thereby close the electrical circuit between the power terminal and the first electrical connector and release the depressible switch into the extended position when unnested from the well of the base module.

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 characterised by a device identifier (14) and wherein the devices (10, 11, 12, 13) are realised 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 characterised by a device identifier (14) and wherein each device (10, 11, 12, 13) is realised 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) realised to collect network descriptive information (40, 41, 42, 43) provided by the devices (10, 11, 12, 13); a topology discovery unit (53) realised 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) realised to compare the derived network topology (T) to the installation plan (3) to allocate a physical location descriptor (31) to a device identifier (14).

Remote controllers, positioning systems, and methods configured for the efficient assignment of addresses in a coded lighting positioning system are proposed. Particularly, a proposed remote controller comprises a receiver for receiving coded light from a light source in a coded lighting positioning system, where the coded light comprises an initial light source identifier of the light source. The remote controller also comprises a processing unit for assigning a modified light source identifier to the light source based on the received coded light, and a transmitter for transmitting the modified light source identifier to the light source. The modified light source identifier is a locally unique identifier used to provide positional information.

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 lighting system comprises at least one network-capable infrastructure device and a commissioning device. The infrastructure device, such as a ballast or a luminaire, includes a first communication unit configured to communicate with at least one other infrastructure device, and a second communication unit. The commissioning device comprises a commissioning communication unit configured to communicate with the second communication unit of the infrastructure device. The infrastructure device receives a key information via the second communication unit and communicates via the first communication unit with the at least one other infrastructure device using the received key information.

A design software, e.g., a graphical user interface (GUI) software, may be used to design and/or configure a load control system. The design software may be executed on a network device (e.g., a personal computer, a laptop, a tablet, or a smart phone). The design software may allow for easy configuration of load control panels and effortless multiplication of configured panels during the design of the load control system. Each load control panel may have a plurality of control devices, such as load control devices (e.g., power modules, dimming modules, and/or switching modules), system controllers, and/or power supplies. The design software may allow for the configuration of load control panels having different types and numbers of control devices. In addition, the design software may allow for the multiplication of load control panels having the same configuration (e.g., the same type and number of control devices).

The invention provides a commissioning device for commissioning building technology devices, in particular operating devices for lighting means, the commissioning device comprising at least one optical sensor, in particular a 3D camera, configured to obtain images containing spatial information of three dimensions and to receive optical communication signals emitted from a building technology device, at least one processing unit configured to process received optical communication signals and to process the spatial images. The at least one processing unit is configured to compute spatial position of the building technology device by processing the produced spatial images and by evaluating the spatial information, wherein the at least one processing unit is configured to process the optical communication signals received from the building technology device in order to obtain information identifying the building technology device, and wherein the at least one processing unit is configured to associate the computed spatial position of the building technology device with the processed visual signals.

A load control system may include control devices capable of being associated with each other at one or more locations for performing load control. Control devices may include control-source devices and/or control-target devices. A location beacon may be discovered and a unique identifier in the location beacon may be associated with a unique identifier of one or more control devices. Upon subsequent discovery of the location beacon, the associated load control devices may be controlled. The beacons may be communicated via radio frequency signals, visible light communication, and/or audio signals. The visible light communication may be used to communicate other types of information to devices in the load control system. The visible light communication may be used to identify link addresses for communicating with load control devices, load control instructions, load control configuration instructions, network communication information, and/or the like. The information in the beacons may be used to commission and/or control the load control system.