A 6.4 Tbps silicon-based photonics engine transceiver chip module for high-speed optical communication manufactured based on processing techniques of semiconductors such as silicon-on-insulator (SOI) and indium phosphide (InP). The photonics engine transceiver chip module uses a silicon photonic chip as a substrate, and optical chips of an InP laser and an optical amplifier are heterogeneously integrated with the silicon photonic chip through bonding or flip-chip soldering. As a pump light source, the laser generates a soliton-based optical frequency comb by using an ultra-low loss silicon nitride (SiN) resonator cavity, and can be used as a multi-wavelength laser. This reduces use of a single-wavelength laser chip, reduces a power consumption and heat conduction of a laser in an optical chip of a photonic engine, and improves an integration level of an optical device. The optical frequency comb generates an optical carrier with wide bandwidth coverage and a large quantity of wavelengths.

A random acoustic phase scrambler device is installed in-line with a telecommunications fiber link to prevent voice detection via fiber links. The device includes a transducer to produce vibrations; a length of optical fiber positioned to receive the vibration from the transducer; and a random acoustic phase driver configured to control the intensity and frequency of the vibrations. The transducer produces randomized vibrations within an acoustic bandwidth. The device is configured to introduce device-induced phase changes to signals within the telecommunications fiber link. The bandwidth of the device-induced phase changes is greater than the bandwidth of voice-induced phase changes, and the device-induced phase changes are greater in intensity than the voice-induced phase changes. The device-induced phase changes mask voice-induced phase changes through the telecommunications fiber link that are otherwise detectable by voice detection equipment tapped to the telecommunications fiber link.

An unused path through which actual data is not transmitted in a long-distance redundant network can be appropriately detect, and this function is realized at low cost. A transmission unit 33 of optical transceivers 21a and 21b connected to each other by an optical fiber cable 22 in an optical transmission system 20 includes a laser 37 for emitting a laser beam serving as an optical signal P1 to the optical fiber cable 22, and an optical intensity control unit 35 for performing control to change the optical level of the optical signal of the laser beam. Each of the optical transceivers 21a and 21b includes a control unit 31 for superimposing each of an idle signal A1, an OAM signal O1, and an actual data signal D1 on an XGMII signal 31s and outputting this XGMII signal 31s to the transmission unit 33 that transmits the optical signal P1, and a signal determination unit 32 for determining unique information regarding each signal output to the transmission unit 33 and outputting a determination result signal 32s. The optical intensity control unit 35 performs control to change the optical level of the optical signal P1 on which a signal of the determination of each signal indicated by the determination result signal 32s is superimposed to different optical levels L1 to L3 between the signals.

Disclosed herein are various embodiments for high performance wireless data transfers. In an example embodiment, laser chips are used to support the data transfers using laser signals that encode the data to be transferred. The laser chip can be configured to (1) receive a digital signal and (2) responsive to the received digital signal, generate and emit a variable laser signal, wherein the laser chip comprises a laser-emitting epitaxial structure, wherein the laser-emitting epitaxial structure comprises a plurality of laser-emitting regions within a single mesa structure that generate the variable laser signal. Also disclosed are a number of embodiments for a photonics receiver that can receive and digitize the laser signals produced by the laser chips. Such technology can be used to wireless transfer large data sets such as lidar point clouds at high data rates.

Disclosed herein are various embodiments for high performance wireless data transfers. In an example embodiment, laser chips are used to support the data transfers using laser signals that encode the data to be transferred. The laser chip can be configured to (1) receive a digital signal and (2) responsive to the received digital signal, generate and emit a variable laser signal, wherein the laser chip comprises a laser-emitting epitaxial structure, wherein the laser-emitting epitaxial structure comprises a plurality of laser-emitting regions within a single mesa structure that generate the variable laser signal. Also disclosed are a number of embodiments for a photonics receiver that can receive and digitize the laser signals produced by the laser chips. Such technology can be used to wireless transfer large data sets such as lidar point clouds at high data rates.

An optical transmission/reception unit includes a carrier rotatable around an axis of rotation, an optical receiver arranged at the carrier on the axis of rotation so as to receive an optical reception signal from a first direction, an optical transmitter arranged at the carrier adjacent to the optical receiver so as to emit an optical transmission signal in a second direction, and a transmission/reception optic arranged at the carrier on the axis of rotation above the optical receiver and extending across the optical receiver and the optical transmitter, wherein the transmission/reception optic includes a reception optic and a transmission optic arranged in the reception optic, wherein the reception optic is configured to guide the optical reception signal striking the transmission/reception optic towards the optical receiver on the axis of rotation.

An optical transmission/reception unit includes a carrier rotatable around an axis of rotation, an optical receiver arranged at the carrier on the axis of rotation so as to receive an optical reception signal from a first direction, an optical transmitter arranged at the carrier adjacent to the optical receiver so as to emit an optical transmission signal in a second direction, and a transmission/reception optic arranged at the carrier on the axis of rotation above the optical receiver and extending across the optical receiver and the optical transmitter, wherein the transmission/reception optic includes a reception optic and a transmission optic arranged in the reception optic, wherein the reception optic is configured to guide the optical reception signal striking the transmission/reception optic towards the optical receiver on the axis of rotation.

A system for creating an adjustable delay in an optical signal. The system has an input interface for receiving an optical input signal. The system has a first optical modulator configured to shift the frequency of the optical input signal depending on a setting of the first optical modulator, thereby generating a modulated optical signal. The system includes at least two frequency selective reflectors configured to reflect the modulated optical signal, thereby providing a reflected signal. The system has a control circuit that adapts the setting of the first optical modulator such that a frequency shift of the optical input signal introduced by the first optical modulator is set by the control circuit. The frequency shift introduced by the first optical modulator corresponds to an operational frequency of one of the at least two frequency selective reflectors associated with the setting of the first optical modulator. The system has an output fiber that receives the reflected signal from the corresponding frequency selective reflector.

A system for creating an adjustable delay in an optical signal. The system has an input interface for receiving an optical input signal. The system has a first optical modulator configured to shift the frequency of the optical input signal depending on a setting of the first optical modulator, thereby generating a modulated optical signal. The system includes at least two frequency selective reflectors configured to reflect the modulated optical signal, thereby providing a reflected signal. The system has a control circuit that adapts the setting of the first optical modulator such that a frequency shift of the optical input signal introduced by the first optical modulator is set by the control circuit. The frequency shift introduced by the first optical modulator corresponds to an operational frequency of one of the at least two frequency selective reflectors associated with the setting of the first optical modulator. The system has an output fiber that receives the reflected signal from the corresponding frequency selective reflector.

The architecture integrates electronic circuitry with highly parallel (>100 elements) surface-normal optoelectronic devices for the purpose of transmitting optical communication signals over a transmission channel. Local electronic circuitry is integrated very close (<100 um) to the optical element, which simplifies the electrical characteristics such that the electronic circuitry can perform better in terms of power dissipation, area utilization, and accuracy of the transmitted and received optical emissions.