In order to suppress any reduction in the reception performance of an optical transceiver, the optical transceiver includes a light source, an optical splitter that splits the output of the light source into a first split light and a second split light, an optical modulation unit that modulates the first split light, a coherent receiver that causes the inputted received light to interfere with the second split light, and a first control unit that controls the split ratio of the optical splitter on the basis of the reception characteristic of the received light received by the coherent receiver.

An apparatus at least includes a processor to, after a first signal passes through a narrowband photodetector, perform frequency mix of the first signal with a first reference signal and a second reference signal respectively and perform noise reduction, to obtain a first detection signal and a second detection signal. The first signal is obtained after a measurement signal passes through a filtering module of an optical transmitting end, the measurement signal being transmitted in a path of multiple branches, signals not transmitted in other paths of the multiple branches, a frame structure of the measurement signal including at least one two-tone signal, two tones in the two-tone signal having a fixed tone interval. The processor is to calculate group delays at multiple frequency bins according to the first detection signal and the second detection signal; and determine a phase response of the filtering module of the optical transmitting end in the path according to the group delays at multiple frequency bins.

An interconnect transceiver for transmitting and receiving optical signals, comprising an electronics module with a transceiver engine, and a photonics module with a laser source, a modulator, a photodetector to monitor the laser, one to receive an external optical signal, and a controller to operate the laser source and the laser source modulator, an electronic switch having two states is proposed. The first state is to allow monitoring of the modulated laser source by the transceiver engine, so as to acquire a reference set of operating parameters, and the second state is where a signal from the modulated laser source is directed to the controller, such as to allow real-time control of the source of the transmitting laser and modulator by the controller.

A transmitting and receiving device includes a controller, a driver, a specific pattern generator, a transmitting signal detector, an amplifier, a differential amplifier, an average current detector, and a received signal detector. In a non-signal period, the controller causes a current signal to be input from the driver to a laser diode and causes an optical signal to be output from the laser diode. When an optical signal of a specific pattern output from the other-side laser diode reaches a photodiode over a period of length that depends on an average value of a current signal output from the other-side photodiode that receives the optical signal, the controller adjusts a magnitude of the current signal input from the driver to the laser diode based on the length of the period of the optical signal of the specific pattern.

An optical communication system includes an optical module and a host. The optical module has a fiber connector and a laser condition pin, wherein the fiber connector is configured to connect to a laser output of an external laser source. The optical module is configured to set an output of the laser condition pin to have a first value when detecting a laser beam through the fiber connector. The host is connected to the laser condition pin and has a control connector, wherein the control connector is configured to connect to the external laser source. The host is configured to output a release signal through the control connector when detecting the first value on the laser condition pin, wherein the release signal changes the laser output from outputting a laser beam having a first power to outputting a laser beam having a second power higher than the first power.

An optical module includes a shell, a circuit board, a light source and a silicon optical chip. The light source is configured to emit light. The silicon optical chip includes a modulator, and the modulator is configured to receive the light emitted by the light source and modulate the light into an optical signal. The circuit board includes a first sampling circuit, a second sampling circuit and a processing circuit. The first sampling circuit is configured to generate a first sampling signal. The second sampling circuit is configured to generate a second sampling signal. The processing circuit is configured to receive the first sampling signal and the second sampling signal, and send a driving signal to the modulator according to a difference between an amplitude of the first sampling signal and an amplitude of the second sampling signal, so as to control an electric heating of the modulator.

An optical communication system includes an optical module and a host. The optical module has a fiber connector and a laser condition pin, wherein the fiber connector is configured to connect to a laser output of an external laser source. The optical module is configured to set an output of the laser condition pin to have a first value when detecting a laser beam through the fiber connector. The host is connected to the laser condition pin and has a control connector, wherein the control connector is configured to connect to the external laser source. The host is configured to output a release signal through the control connector when detecting the first value on the laser condition pin, wherein the release signal changes the laser output from outputting a laser beam having a first power to outputting a laser beam having a second power higher than the first power.

A short-waveband active optical component based on a vertical emitting laser and a multi-mode optical fiber has an emitting end and a receiving end. In the emitting end, multiple VCSELs generate multiple optical signals of different wavelengths, and multiple photodiodes in the receiving end receive the optical signals emitted by the VCSELs. Both ends use a focusing lens array to collimate and focus the optical signals A Z-block-shaped prism performs a light combining function at the emitting end, while another Z-block-shaped prism performs a light splitting function at the receiving end. Both ends use a focusing lens for collimating and focusing the optical signals at ends of a multi-mode optical fiber, which is used for transmitting the optical signals generated by the VCSELs. The short-waveband active optical component has a small size and a high transmission rate.

An apparatus at least includes a processor to, after a first signal passes through a narrowband photodetector, perform frequency mix of the first signal with a first reference signal and a second reference signal respectively and perform noise reduction, to obtain a first detection signal and a second detection signal. The first signal is obtained after a measurement signal passes through a filtering module of an optical transmitting end, the measurement signal being transmitted in a path of multiple branches, signals not transmitted in other paths of the multiple branches, a frame structure of the measurement signal including at least one two-tone signal, two tones in the two-tone signal having a fixed tone interval. The processor is to calculate group delays at multiple frequency bins according to the first detection signal and the second detection signal; and determine a phase response of the filtering module of the optical transmitting end in the path according to the group delays at multiple frequency bins.

Examples herein relate to optical systems. In particular, implementations herein relate to an optical system including an optical transmitter configured to transmit optical signals. The optical transmitter includes a first optical source and a second optical source coupled to the first optical source and injection seeded by the first optical source. The optical transmitter further includes an output coupler, the second optical source coupled to the optical coupler via an output waveguide and configured to emit light having multiple different wavelengths through the output waveguide. In some implementations, the second optical source is self-injection seeded.