A photonic computing system is presented. The system comprises an arrangement of multiple photonic processing units having input and output ports, each of the photonic processing units comprising an array of photonic guiding units configured to define propagation conditions for multiple light fields associated with one or more optical processing tasks. The system also comprises a plurality of optical connectors, each of the optical connectors performing light field to light field coupling between the input and output ports of the photonic processing units, thereby providing a network of communicating processing units. The photonic computing system can be configured as a module enabling its housing in a network rack.

A communication device designed for an interior compartment, for example of a motor vehicle. The device includes a radiofrequency communication module and an interface module which is operationally coupled to the radiofrequency communication module in order to receive a digital signal generated by the radiofrequency communication module, and to modulate an electric power supply signal for at least one lamp, according to the digital signal, in order to generate a modulation of light emitted by the lamp according to the digital signal received from the radiofrequency communication module.

An optical communications system includes a laser transmitter to generate an optical signal and a first optical fiber network coupled to transmit the optical signal from the laser transmitter system. A first latchable, asymmetric coupler is disposed along the first optical fiber network to receive the optical signal, and has a first tap output that receives a selected and alterable first fraction of the optical signal. A second latchable, asymmetric coupler is disposed along the first optical fiber network to receive the optical signal from the first latchable asymmetric coupler and has a second tap output that receives a selected and alterable second fraction of the optical signal incident at the second latchable. In certain embodiments the first and second couplers are capable of operating at any of at least three tapping fractions.

An optical communications system includes a laser transmitter to generate an optical signal and a first optical fiber network coupled to transmit the optical signal from the laser transmitter system. A first latchable, asymmetric coupler is disposed along the first optical fiber network to receive the optical signal, and has a first tap output that receives a selected and alterable first fraction of the optical signal. A second latchable, asymmetric coupler is disposed along the first optical fiber network to receive the optical signal from the first latchable asymmetric coupler and has a second tap output that receives a selected and alterable second fraction of the optical signal incident at the second latchable. In certain embodiments the first and second couplers are capable of operating at any of at least three tapping fractions.

Power sourcing equipment of a power-over-fiber system includes a first laser, a second laser, and a light input/output part. The first laser oscillates with electric power to output feed light. The second laser oscillates with electric power to output feed light. The light input/output part inputs first feed light output by the first laser and second feed light output by the second laser to a single channel of an optical fiber. A light intensity distribution of the first feed light at an output end face of the channel differs from a light intensity distribution of the second feed light at the output end face of the channel. The first feed light and the second feed light are simultaneously input to the channel to reduce non-uniformity of a light intensity distribution at the output end face. Further, incident angles α1 and α2 are different from each other to reduce the non-uniformity of the light intensity distribution at the output end face.

Power sourcing equipment of a power-over-fiber system includes a first laser, a second laser, and a light input/output part. The first laser oscillates with electric power to output feed light. The second laser oscillates with electric power to output feed light. The light input/output part inputs first feed light output by the first laser and second feed light output by the second laser to a single channel of an optical fiber. A light intensity distribution of the first feed light at an output end face of the channel differs from a light intensity distribution of the second feed light at the output end face of the channel. The first feed light and the second feed light are simultaneously input to the channel to reduce non-uniformity of a light intensity distribution at the output end face. Further, incident angles α1 and α2 are different from each other to reduce the non-uniformity of the light intensity distribution at the output end face.

Provided are a power management method and apparatus of an ONU supporting a slicing function. A power management method performed by a power management apparatus of an ONU supporting a slicing function includes receiving a first message for discovering a power management attribute of an ONU including at least one slice from an optical line terminal (OLT), transmitting a second message including the power management attribute of the ONU to the OLT in response to the first message received, receiving a third message for setting up a power management parameter for each slice included in the ONU from the OLT, setting up the power management parameter for each slice included in the ONU based on the third message received, and transmitting a fourth message including a set up result of the power management parameter for each slice included in the ONU to the OLT.

Provided are a power management method and apparatus of an ONU supporting a slicing function. A power management method performed by a power management apparatus of an ONU supporting a slicing function includes receiving a first message for discovering a power management attribute of an ONU including at least one slice from an optical line terminal (OLT), transmitting a second message including the power management attribute of the ONU to the OLT in response to the first message received, receiving a third message for setting up a power management parameter for each slice included in the ONU from the OLT, setting up the power management parameter for each slice included in the ONU based on the third message received, and transmitting a fourth message including a set up result of the power management parameter for each slice included in the ONU to the OLT.

An optical fiber cable for feed-light transmission includes an optical fiber, a cable sheath, and a phosphor layer. The optical fiber includes a channel of feed light. The cable sheath is located at a periphery of the optical fiber and has a property of shielding the feed light. The phosphor layer is located between the optical fiber and the cable sheath and emits fluorescence upon receiving the feed light. The cable sheath has a property of allowing at least part of the fluorescence emitted by the phosphor layer upon receiving the feed light to pass therethrough.

An optical fiber cable for feed-light transmission includes an optical fiber, a cable sheath, and a phosphor layer. The optical fiber includes a channel of feed light. The cable sheath is located at a periphery of the optical fiber and has a property of shielding the feed light. The phosphor layer is located between the optical fiber and the cable sheath and emits fluorescence upon receiving the feed light. The cable sheath has a property of allowing at least part of the fluorescence emitted by the phosphor layer upon receiving the feed light to pass therethrough.