An optical communication system using a photonic lantern for fine point tracking is disclosed. The optical communication system may comprise a photonic lantern, a signal processing unit including one or more fiber splitters to sample a fraction of a received signal in each single mode fiber of the photonic lantern, and one or more intensity sensors positioned in one arm of each fiber splitter, and used for monitoring fiber-specific intensity data associated with each of the single-mode fibers. The system may further include a fine pointing assembly and a controller for controlling a driver of the fine pointing assembly.

An optical communication system using a photonic lantern for fine point tracking is disclosed. The optical communication system may comprise a photonic lantern, a signal processing unit including one or more fiber splitters to sample a fraction of a received signal in each single mode fiber of the photonic lantern, and one or more intensity sensors positioned in one arm of each fiber splitter, and used for monitoring fiber-specific intensity data associated with each of the single-mode fibers. The system may further include a fine pointing assembly and a controller for controlling a driver of the fine pointing assembly.

Systems and methods are described for transmitting information optically. For instance, a system may include an optical source configured to generate a beam of light. The system may include at least one modulator configured to encode data on the beam of light to produce an encoded beam of light/encoded plurality of pulses. The system may include a spectrally-equalizing amplifier configured to receive the encoded beam of light/encoded plurality of pulses from the at least one modulator and both amplify and filter the encoded beam of light/encoded plurality of pulses to produce a filtered beam of light/filtered plurality of pulses, thereby spectrally equalizing a gain applied to the encoded beam of light. In some cases, the system may slice the beam of slight, to ensure a detector has impulsive detection. In some cases, the system may include a temperature controller to shift a distribution curve of wavelengths of the optical source.

Systems and methods are described for transmitting information optically. For instance, a system may include an optical source configured to generate a beam of light. The system may include at least one modulator configured to encode data on the beam of light to produce an encoded beam of light/encoded plurality of pulses. The system may include a spectrally-equalizing amplifier configured to receive the encoded beam of light/encoded plurality of pulses from the at least one modulator and both amplify and filter the encoded beam of light/encoded plurality of pulses to produce a filtered beam of light/filtered plurality of pulses, thereby spectrally equalizing a gain applied to the encoded beam of light. In some cases, the system may slice the beam of slight, to ensure a detector has impulsive detection. In some cases, the system may include a temperature controller to shift a distribution curve of wavelengths of the optical source.

Provided is an optical signal processing apparatus capable of reducing an influence of wavelength dispersion in wavelength division multiplexing communication. An optical signal processing apparatus of the present disclosure includes: an input waveguide that inputs a wavelength multiplexed signal; an optical branching waveguide configured to branch the wavelength multiplexed signal from the input waveguide into a plurality of arm waveguides; a plurality of wavelength selection waveguides connected to the plurality of arm waveguides, each of the plurality of wavelength selection waveguides being configured to select an optical signal from among the branched wavelength multiplexed signals; and an optical merging waveguide configured to merge light from the plurality of arm waveguides.

Provided is an optical signal processing apparatus capable of reducing an influence of wavelength dispersion in wavelength division multiplexing communication. An optical signal processing apparatus of the present disclosure includes: an input waveguide that inputs a wavelength multiplexed signal; an optical branching waveguide configured to branch the wavelength multiplexed signal from the input waveguide into a plurality of arm waveguides; a plurality of wavelength selection waveguides connected to the plurality of arm waveguides, each of the plurality of wavelength selection waveguides being configured to select an optical signal from among the branched wavelength multiplexed signals; and an optical merging waveguide configured to merge light from the plurality of arm waveguides.

An electro-optical chip includes a plurality of transmit macros, each of which includes an optical waveguide and a plurality of ring resonators positioned along the optical waveguide. An optical distribution network is implemented onboard the electro-optical chip. The optical distribution network has a plurality of optical inputs and a plurality of optical outputs. The optical distribution network conveys a portion of light received at each and every one of the plurality of optical inputs to each of the plurality of optical outputs, such that light conveyed to each of the plurality of optical outputs includes all wavelengths of light conveyed to the plurality of optical inputs. Each of the plurality of optical outputs is optically connected to the optical waveguide in a corresponding one of the plurality of transmit macros. The electro-optical chip is optically connected to a remote optical power supply.

An electro-optical chip includes a plurality of transmit macros, each of which includes an optical waveguide and a plurality of ring resonators positioned along the optical waveguide. An optical distribution network is implemented onboard the electro-optical chip. The optical distribution network has a plurality of optical inputs and a plurality of optical outputs. The optical distribution network conveys a portion of light received at each and every one of the plurality of optical inputs to each of the plurality of optical outputs, such that light conveyed to each of the plurality of optical outputs includes all wavelengths of light conveyed to the plurality of optical inputs. Each of the plurality of optical outputs is optically connected to the optical waveguide in a corresponding one of the plurality of transmit macros. The electro-optical chip is optically connected to a remote optical power supply.

Some implementations described herein provide an optical receiver system. The optical receiver system includes optical circuitry that may include a phase shifter device, a demultiplexer device, a power combiner device, and/or a power splitter device. Different combinations of such devices within the optical circuitry may balance and/or reduce photocurrents within the photodiode device to improve a performance (e.g., a bandwidth) of the optical receiver system relative to another optical receiver system that does not include the optical circuitry.

Some implementations described herein provide an optical receiver system. The optical receiver system includes optical circuitry that may include a phase shifter device, a demultiplexer device, a power combiner device, and/or a power splitter device. Different combinations of such devices within the optical circuitry may balance and/or reduce photocurrents within the photodiode device to improve a performance (e.g., a bandwidth) of the optical receiver system relative to another optical receiver system that does not include the optical circuitry.