Disclosed herein are methods, devices, and system for beam forming and beam steering within ultra-wideband, wireless optical communication devices and systems. According to one embodiment, a free space optical (FSO) communication apparatus is disclosed. The FSO communication apparatus includes a semiconductor optical device configured to have a transient response time of less than 500 picoseconds (ps), a lens, and a first band select filter.

The disclosure relates to an automation device of a group of automation devices, comprising: a communication interface configured to communicate with a second automation device of the group of automation devices via a communication network; wherein the communication interface is configured to receive a status message of the second automation device that indicates a state or a change in state of the second automation device; and a light source configured to emit a light signal indicating the state or the change in state of the second automation device in response to the receiving of the status message.

The disclosure relates to an automation device of a group of automation devices, comprising: a communication interface configured to communicate with a second automation device of the group of automation devices via a communication network; wherein the communication interface is configured to receive a status message of the second automation device that indicates a state or a change in state of the second automation device; and a light source configured to emit a light signal indicating the state or the change in state of the second automation device in response to the receiving of the status message.

Embodiments of the present disclosure relate to a display device and a server. More specifically, there can be provided a display device which includes a light receiving transistor and a light receiving layer positioned in an active region, and provides an optical signal receiver in the active region, so that there is no need to secure a separate space for the optical signal receiver and high-speed optical communication is possible.

A mobile terminal is a communication device that communicates using visible light, and includes: a plurality of light emitters, each of which is disposed along the front surface of the mobile terminal and transmits a visible light signal; and a plurality of light receivers, each of which is disposed along the front surface and receives a visible light signal. The plurality of light emitters are disposed on the left side of all of the plurality of light receivers, and the plurality of first light receivers are disposed on the right side of all of the plurality of light emitters.

A mobile terminal is a communication device that communicates using visible light, and includes: a plurality of light emitters, each of which is disposed along the front surface of the mobile terminal and transmits a visible light signal; and a plurality of light receivers, each of which is disposed along the front surface and receives a visible light signal. The plurality of light emitters are disposed on the left side of all of the plurality of light receivers, and the plurality of first light receivers are disposed on the right side of all of the plurality of light emitters.

A method and apparatus for use in an optical wireless communication system that enable communication of data, e.g. LiFi, and wherein fast handover can be achieved by having neighboring access points (AP1, AP2) announce themselves using very short frames, that get picked up by user devices (EP1) that detect the identity of a neighbor access point (AP2) and then communicate this to the current access point (AP1) to share information on the user device (EP1) with its neighbor access point (AP2), so that the neighbor access point (AP2) can be pre-configured to allocate resources and/or synchronize.

A method and apparatus for use in an optical wireless communication system that enable communication of data, e.g. LiFi, and wherein fast handover can be achieved by having neighboring access points (AP1, AP2) announce themselves using very short frames, that get picked up by user devices (EP1) that detect the identity of a neighbor access point (AP2) and then communicate this to the current access point (AP1) to share information on the user device (EP1) with its neighbor access point (AP2), so that the neighbor access point (AP2) can be pre-configured to allocate resources and/or synchronize.

Systems and methods for forming a verified secure wireless connection are disclosed. One system includes a first device with a first transceiver and a second device with a second transceiver. The second device does not include a display or any other means for providing high resolution visible light information. The system also includes a visible light signal source on the second device. The first and second devices store computer-readable instructions to initialize a secure wireless connection using the first transceiver and the second transceiver. The second device also stores computer-readable instructions to generate a visible light signal using the visible light source. The first device stores computer-readable instructions to verify the secure wireless connection using the visible light signal.

Systems and methods for forming a verified secure wireless connection are disclosed. One system includes a first device with a first transceiver and a second device with a second transceiver. The second device does not include a display or any other means for providing high resolution visible light information. The system also includes a visible light signal source on the second device. The first and second devices store computer-readable instructions to initialize a secure wireless connection using the first transceiver and the second transceiver. The second device also stores computer-readable instructions to generate a visible light signal using the visible light source. The first device stores computer-readable instructions to verify the secure wireless connection using the visible light signal.