Embodiments of this application disclose a power control method, and belong to the field of wireless communications technologies. The method includes: receiving, by a terminal device, signaling from a radio access network device; learning, by the terminal device based on the signaling, of a slot of power control information required by the terminal device to perform uplink sending; and obtaining, by the terminal device in the slot of the power control information required for uplink sending, the power control information required for uplink sending, so that the terminal device dynamically obtains uplink power control information of the terminal device without being based on a static uplink-downlink subframe configuration in the prior art.

Embodiments of this application disclose a power control method, and belong to the field of wireless communications technologies. The method includes: receiving, by a terminal device, signaling from a radio access network device; learning, by the terminal device based on the signaling, of a slot of power control information required by the terminal device to perform uplink sending; and obtaining, by the terminal device in the slot of the power control information required for uplink sending, the power control information required for uplink sending, so that the terminal device dynamically obtains uplink power control information of the terminal device without being based on a static uplink-downlink subframe configuration in the prior art.

A method of controlling an optical amplifying system that processes an optical signal with the PAM4 mode is disclosed. The optical amplifying system includes a variable optical attenuator (VOA) and a semiconductor optical amplifier (SOA). The VOA attenuates the optical signal such that a maximum optical power thereof corresponding to one of the physical levels of the PAM4 signal becomes equal to a preset optical level for which the SOA may be linearly operable. The SOA may amplify the thus attenuated optical signal with a fixed optical gain.

A method of controlling an optical amplifying system that processes an optical signal with the PAM4 mode is disclosed. The optical amplifying system includes a variable optical attenuator (VOA) and a semiconductor optical amplifier (SOA). The VOA attenuates the optical signal such that a maximum optical power thereof corresponding to one of the physical levels of the PAM4 signal becomes equal to a preset optical level for which the SOA may be linearly operable. The SOA may amplify the thus attenuated optical signal with a fixed optical gain.

The present disclosure provides a method and a device for amplifying uplink light of a passive optical network, and a computer-readable storage medium. The passive optical network includes an optical network unit, an optical line terminal, and an optical amplifier provided between the optical network unit and the optical line terminal, and the method include: receiving a registration signal transmitted from the optical line terminal; determining a gain value of the optical amplifier, and performing gain value adjustment on the optical amplifier according to the determined gain value; and completing registration when an uplink optical signal transmitted to the optical line terminal through the optical amplifier reaches preset power.

A method and apparatus for controlling an optical switch. The switch includes a switching fabric and optical amplifiers for amplifying optical signals. A configuration for the switching fabric is generated and implemented. The configuration indicates a set of optical paths between switching fabric input ports and the output ports. Optical path losses through the switching fabric vary based on the configuration. An amplifier control signal for controlling gains of the optical amplifiers, is also provided. The configuration for the switching fabric is generated based on the gains of the optical amplifiers, the amplifier control signal is generated based on the configuration for the switching fabric, or both.

Techniques and systems for selectively performing band-switching operations are provided. For example, a method, computing device, or computer-program product may be provided, and may include receiving a communication from a first device, wherein the communication is received on a channel of a first WiFi frequency band, wherein the communication is received using a first WiFi circuit of the computing device, and wherein the computing device is a node of a mesh network. The method, computing device, or computer-program product may further include determining whether the first device is a node of the mesh network, determining a second device to which to transmit the communication, and determining whether the second device is a node of the mesh network. The method, computing device, or computer-program product may further include determining whether to transmit the communication to the second device on a second WiFi frequency band, wherein the second WiFi frequency band is different from the first WiFi frequency band, and wherein determining whether to transmit the communication on the second WiFi frequency band depends on whether the first device is a node of the mesh network.

This optical amplification module includes a light source that outputs light of a predetermined wavelength as excitation light, a first optical coupler that splits the excitation light into first excitation light and second excitation light such that an optical power ratio becomes a predetermined ratio, and then couples the first excitation light with a first optical signal and outputs the result, and outputs the second excitation light to a different path from the first optical signal and a first optical amplifier that amplifies and outputs the first optical signal.

This optical amplification module includes a light source that outputs light of a predetermined wavelength as excitation light, a first optical coupler that splits the excitation light into first excitation light and second excitation light such that an optical power ratio becomes a predetermined ratio, and then couples the first excitation light with a first optical signal and outputs the result, and outputs the second excitation light to a different path from the first optical signal and a first optical amplifier that amplifies and outputs the first optical signal.

A free-space optical communication method is provided. An example method may include generating an optical frequency comb comprising a first tone and a second tone different from the first tone. The method may include modulating, by a first modulator of a first device, the first tone to generate a first signal comprising data. The method may include modulating, by a second modulator of the first device, the second tone to generate a second signal that is a phase conjugate of the first signal. The method may include transmitting, via free-space and to a second device, a communication signal having the first signal and the second signal.