An optoelectronic device equips an access point of an optical wireless communication system and includes a transmitting optoelectronic module converting a digital signal into a light signal to be transmitted, a receiving optoelectronic module converting a received light signal into a digital signal, a control module controlling the transmitting optoelectronic module and the receiving optoelectronic module, and a power supply module supplying the transmitting optoelectronic module with a current selected by the control module, and the receiving optoelectronic module and the control module with voltages selected by the control module.

A method by a coordination node is provided for controlling communications between Li-Fi APs and UEs. The method includes receiving peer connectivity reports from Li-Fi APs which identify Li-Fi APs having at least partially overlapping coverage areas, and developing a handover pathway data structure, based on the peer connectivity reports, that identifies Li-Fi APs that can receive communication handover from other identified Li-Fi APs. The method further includes determining an identifier of a first Li-Fi AP providing Li-Fi communication service for a UE, and accessing the handover pathway data structure using the identifier of the first Li-Fi AP to determine an identifier of a second Li-Fi AP to which handover from the first Li-Fi AP can be performed. The method then initiates handover of the Li-Fi communication service for the UE from the first Li-Fi AP to the second Li-Fi AP.

A person support apparatus includes a first transceiver adapted to wirelessly communicate with a second transceiver of a headwall interface that is positioned off of the person support apparatus. A communication link is automatically established between the first and second transceivers without requiring a user of the person support apparatus to activate a designated control and without requiring the user to identify the headwall interface. The first transceiver includes a unique identifier assigned to the headwall interface in its messages to the headwall interface. The first transceiver may also automatically transmit a disconnect signal to the headwall interface indicating the termination of the communication link is not accidental. The disconnect signal is sent based on one or more of the following: (1) a brake being off, (2) an A/C power cord being unplugged; and/or (3) a signal strength between the transceivers decreasing.

A reconfigurable free-space optical inter-rack network includes a plurality of server racks, each including at least one switch mounted on a top thereof, where each top-mounted switch includes a plurality of free-space-optic link connector, each with a free-space optical connection to a free-space-optic link connector on another top-mounted switch, a single ceiling mirror above the plurality of server racks that substantially covers the plurality of server racks, wherein the single ceiling mirror redirects optical connections between pairs of free-space-optic link connectors to provide a clear lines-of-sight between each pair of connected free-space-optic link connectors, and a controller that preconfigures a free-space optical network connecting the plurality of server racks by establishing connections between pairs of free-space-optic link connectors, and that reconfigures connections between pairs of free-space-optic link connectors in response to network traffic demands and events.

Devices, systems, and methods for providing wireless personal area networks (PANs) and local area networks (LANs) using visible and near-visible optical spectrum. Various constructions and material selections are provided herein. According to one embodiment, a light-emitting diode (LED) includes a substrate, a carrier confinement (CC) region positioned over the substrate, and an active region position over the CC region. The CC region includes a first CC layer comprising aluminum gallium nitride and a second CC layer position over the first CC layer. The second CC layer also includes aluminum gallium nitride. The active region is configured to have a transient response time of less than 500 picoseconds (ps).

A self-contained positioning assembly includes a wiring compartment that is configured to receive external power, a power supply disposed within the wiring compartment that is configured to convert the external power to low voltage power, a housing, a conduit that couples the wiring compartment with the housing, an electronic positioning beacon disposed within the housing, and wiring that transmits the low voltage power from the power supply, through the conduit, to the electronic positioning beacon within the housing. The electronic positioning beacon is configured to receive the low voltage power and transmit electronic positioning signals in response.

A wireless communication system comprises a base station and one or more relay docks and transmits directional wave signals between components using high frequency waves, such as millimeter waves. A beam forming decision engine utilizes position information collected from one or more position or motion sensors of a user device to determine a direction in which to form a directional wave signal being transmitted between components of the wireless communication system.

Disclosed herein are methods, devices, and systems for providing timing and bandwidth management of ultra-wideband, wireless data channels (including radio frequency and wireless optical data channels). According to one embodiment, a hub apparatus is disclosed for providing out-of-band bandwidth management for a free-space-optical (FSO) data channel associated with a first device. The hub apparatus includes a processor, a memory coupled with the processor, an FSO transmitter coupled with the processor, and an FSO receiver coupled with the processor. The FSO transmitter may be configured to transmit a control signal comprising timing information and bandwidth management information.

A system and a method for generated synchronized audible communications are provided. In one aspect, a system includes a suite of appliances, including at least a first and second appliance. Each appliance has a speaker operable to generate one or more audible communications. The system includes one or more controllers that output one or more sound commands that cause the speakers of the appliances to generate their respective audible communications. One or more of the appliances include a proximity device operable to detect whether a user is within a proximity range thereof. In some instances, the speakers can generate audible communications to amplify their audible communications. In other instances, the speakers can generate audible communications to create localization cues for directing a user's attention to a particular appliance.

Joint power allocation and cell formation for energy efficient (EE) visible light communication (VLC) networks is described. A set of rules for clustering users and then associating all the access points (APs) to the clustered users based on a proposed metric is developed. The energy efficiency is maximized by allocating power to users based on quality of service (QoS) constraints. The present disclosure jointly allocates the power and decides which APs must participate in communication and which ones must be switched off to minimize inter-cell interference. Numerical results demonstrate a significant improvement in energy efficiency compared to the traditional methods of clustering and AP assignment.