An optical wireless communication system comprises: a first device comprising a transceiver apparatus; and a plurality of further devices each comprising respective further transceiver apparatus, wherein the first device is configured to communicate via at least one optical channel with the plurality of further devices, and the transceiver apparatus of the first device comprising: a receiver for receiving light (optionally of a first wavelength or range of wavelengths) representing optical wireless communication signals transmitted by the further devices, the receiver comprising at least one photodetector; receiver-side processing circuitry for processing optical wireless communication signals received by the receiver to extract data represented by the received optical wireless communication signals; a transmitter for transmitting further light (optionally of a second wavelength or range of wavelengths)s representing optical wireless communication signals; transmitter-side processing circuitry for producing optical wireless communication signals for transmission by the transmitter; a multiplexer arrangement that is arranged to receive optical wireless communication signals from a plurality of signal paths and to pass the signals to the transmitter for transmission; and a controller for controlling operation of the transceiver apparatus of the first device, wherein a first of the signal paths to the multiplexer arrangement is from the transmitter-side processing circuitry; a second of the signal paths to the multiplexer arrangement is from the receiver-side; and the controller controls operation of the transceiver apparatus so as to pass via the multiplexer arrangement to the transmitter for re-transmission at least part of an optical wireless communication signal received from one of the further devices by the receiver thereby to indicate to the other further devices of the plurality of further devices that an optical channel of the receiver is busy.

An optical wireless communication system comprises: a first device comprising a transceiver apparatus; and a plurality of further devices each comprising respective further transceiver apparatus, wherein the first device is configured to communicate via at least one optical channel with the plurality of further devices, and the transceiver apparatus of the first device comprising: a receiver for receiving light (optionally of a first wavelength or range of wavelengths) representing optical wireless communication signals transmitted by the further devices, the receiver comprising at least one photodetector; receiver-side processing circuitry for processing optical wireless communication signals received by the receiver to extract data represented by the received optical wireless communication signals; a transmitter for transmitting further light (optionally of a second wavelength or range of wavelengths)s representing optical wireless communication signals; transmitter-side processing circuitry for producing optical wireless communication signals for transmission by the transmitter; a multiplexer arrangement that is arranged to receive optical wireless communication signals from a plurality of signal paths and to pass the signals to the transmitter for transmission; and a controller for controlling operation of the transceiver apparatus of the first device, wherein a first of the signal paths to the multiplexer arrangement is from the transmitter-side processing circuitry; a second of the signal paths to the multiplexer arrangement is from the receiver-side; and the controller controls operation of the transceiver apparatus so as to pass via the multiplexer arrangement to the transmitter for re-transmission at least part of an optical wireless communication signal received from one of the further devices by the receiver thereby to indicate to the other further devices of the plurality of further devices that an optical channel of the receiver is busy.

A passenger vehicle optical communication system includes a source vehicle including a light source and an endpoint vehicle including a camera. The source vehicle transmits a series of patterns using the light source to communicate, as one example, state information to the endpoint vehicle.

Embodiments of the present disclosure provides a visible light communication network. The visible light communication network includes a plurality of optical network nodes, any two optical network nodes of the plurality of optical network nodes are connected through an optical connection, the plurality of optical network nodes form at least one optical communication link, and each of the at least one optical communication link includes at least part of the plurality of optical network nodes. A first optical network node is configured to communicate an optical signal with another optical network node through an optical connection between the first optical network node and the other optical network node, and the first optical network node is any optical network node in the optical communication link.

A method for a vehicle-machine interconnection and an apparatus for a vehicle-machine interconnection, relates to the field of communication technology, and specifically relates to the technical field of Internet of Vehicles. A specific implementation scheme includes: first acquiring device information for a direct wireless connection; then sending the device information to an on-board terminal based on an infrared protocol; and finally receiving a connection request based on the device information, and establishing the direct wireless connection with the on-board terminal sending the connection request.

A method for a vehicle-machine interconnection and an apparatus for a vehicle-machine interconnection, relates to the field of communication technology, and specifically relates to the technical field of Internet of Vehicles. A specific implementation scheme includes: first acquiring device information for a direct wireless connection; then sending the device information to an on-board terminal based on an infrared protocol; and finally receiving a connection request based on the device information, and establishing the direct wireless connection with the on-board terminal sending the connection request.

Embodiments of the present disclosure provide a MIMO communication method and system, and a receiver node. The method includes: receiving, by a number of optical detection modules of a receiver node, optical signals transmitted by a number of optical transmission modules of a transmitter node. Different optical detection modules of the receiver node have different orientations, and different optical transmission modules of the transmitter node have different orientations.

Embodiments of the present disclosure provide a MIMO communication method and system, and a receiver node. The method includes: receiving, by a number of optical detection modules of a receiver node, optical signals transmitted by a number of optical transmission modules of a transmitter node. Different optical detection modules of the receiver node have different orientations, and different optical transmission modules of the transmitter node have different orientations.

Materials containing picocrystalline quantum dots that form artificial atoms are disclosed. The picocrystalline quantum dots (in the form of born icosahedra with a nearly-symmetrical nuclear configuration) can replace corner silicon atoms in a structure that demonstrates both short range and long-range order as determined by x-ray diffraction of actual samples. A novel class of boron-rich compositions that self-assemble from boron, silicon, hydrogen and, optionally, oxygen is also disclosed. The preferred stoichiometric range for the compositions is (B.sub.12H.sub.w).sub.xSi.sub.yO.sub.z with 3≤w≤5, 2≤x≤4, 2≤y≤5 and 0≤z≤3. By varying oxygen content and the presence or absence of a significant impurity such as gold, unique electrical devices can be constructed that improve upon and are compatible with current semiconductor technology.

A method for connecting a wireless communication station (STA) with a selected one of a plurality of access points (APs) are described. At least some of the APs are initially substantially unsynchronized in time. The method includes transmitting, by the STA, a beacon request signal via an uplink channel, performing, by the APs and in response to the beacon request signal, a synchronization procedure, the synchronization procedure comprising transmitting, by each of the APs, a respective beacon signal via at least one downlink channel, such that the beacon signals from the plurality of APs are substantially synchronized in time, receiving, by the STA, the beacon signals from the plurality of APs, selecting, by the STA, one of the plurality of APs in dependence on at least one property of the beacon signals, and associating the STA with the selected one of plurality of APs. Related systems and devices are described.