Provided is a lighting system that includes a plurality of luminaires, at least one controller in communication with the luminaires via a communication line in a network, and configured to control the luminaires, and a lighting control system including a smart device which wirelessly communicates with the at least one controller and the plurality of the luminaires, and performs a commissioning operation of the luminaires in the network using visual light communication (VLC).

A lighting system according to the embodiment includes a lighting device; and a graphic user interface displayed on a touch screen of a lighting control device to control the lighting device. The graphic user interface includes a first region to display a map for an installation space of the lighting device and a lighting icon corresponding to the lighting device in the map; and a second region to display a menu for setting a control condition of the lighting device corresponding to the lighting icon. The map includes a plurality of division spaces obtained by dividing the installation space into a plurality of regions and the lighting icon is displayed in a specific division space corresponding to an actual installation portion of the lighting device.

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 communication with non-lighting-system devices at the premises. Each such element has a communication interface system configured to provide a 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.

Various systems and methods facilitate internal communication within a lighting module as well as intercommunication among lighting modules over an external network. The network may be a conventional network managed by a central network controller or may be an ad hoc or mesh networki.e., a scalable network architecture in which any lighting module is a node that can communicate with any other module or network-connected device.

A lighting system utilizes intelligent lighting 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 optical wireless communication with non-lighting-system devices at the premises having optical transmitters and receivers. Each such element has a communication interface system configured to provide the optical wireless data communication link for use by other non-lighting-system devices at the premises via one of visible light spectrum; infrared light; or ultraviolet (UV) light. 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 non-lighting-system devices.

A lighting system according to the embodiment includes a lighting device; and a graphic user interface displayed on a touch screen of a lighting control device to control the lighting device. The graphic user interface includes a first region to display a map for an installation space of the lighting device and a lighting icon corresponding to the lighting device in the map; and a second region to display a menu for setting a control condition of the lighting device corresponding to the lighting icon. The map includes a plurality of division spaces obtained by dividing the installation space into a plurality of regions and the lighting icon is displayed in a specific division space corresponding to an actual installation portion of the lighting device.

A mechanism for handling mirror symmetry and gravity ambiguity in a two-dimensional mesh of devices. A direction of gravity with respect to a first device, of a trio of devices, is determined by a gravitational sensor comprised in the first device. A relative direction of a second and third device with respect to the first device is then ascertained. The direction of gravity, and the relative directions of the first and third device, are then used to determine a handedness of a triangle connecting the three devices with respect to gravity. This handedness with respect to gravity can be propagated throughout the mesh of devices and used to eliminate mirror symmetry and gravity ambiguity in the mesh.

A system of luminaires, which are connected to one another within a mesh network, and which interoperate in accordance with the disclosed method. A receiving luminaire receives a notification message from a second luminaire. The second luminaire can be the luminaire that originates a notification message as a result of sensing occupancy in its vicinity, or the luminaire can be an intermediary node that is relaying the notification message from another luminaire. The notification message comprises a first source address and a first light level. The receiving luminaire modifies a first light output of its lamp, wherein the first light output is based on: (i) the first light level, (ii) a distance between (a) the receiving luminaire and (b) a node corresponding to the first source address, and (iii) whether or not the first source address is a member of a first set of neighbor addresses.

Commissioning a lighting system is disclosed. A user can be provided with a pointing device capable of emitting or returning a signal which can be received by detectors co-located with each fixture in the lighting system. The user can add a fixture to a group by aiming the pointing device at the fixture when the fixture is not assigned to the group, and the user can remove a fixture from a group in the same way when the fixture was previously assigned to the group. Additional user gestures are also disclosed.

The present disclosure provides techniques for a self-commissioning and locating lighting system. The system includes a group of light fixtures, each emitting a unique optical data signal. A remote control device detects the unique optical data signal from the light fixtures when the light fixture is within a visual field of the remote control device. A central controller receives a signal from the remote control device, wherein the signal comprises data regarding the GPS location of the remote control device and the digital identities of the light fixture within the visual field of the remote control, wherein the signal further comprises a control command for operation of the light fixtures, and wherein the central controller sends a control signal to the light fixture implementing the control command.