An optical fiber cable unit has an optical fiber cable obtained by binding a plurality of optical fibers and transmits a laser beam using transmission paths having the optical fibers, respectively. The optical fiber cable unit includes: an input-side connection unit that inputs the laser beam to the optical fibers; a one-end-side connection unit fixed to one end of the optical fiber cable and connected to the input-side connection unit; an other-end-side connection unit fixed to the other end of the optical fiber cable; and an output-side connection unit to which the other-end-side connection unit is connected and in which the laser beam from the optical fibers is output. The input-side connection unit has a switching mechanism that switches the transmission paths for transmitting the laser beam.

A system configured to monitor temperature in a plurality of zones of an aircraft includes an optical fiber with first and second ends, first and second connectors, and a first interrogator. The optical fiber includes a plurality of fiber Bragg gratings disposed in the optical fiber. The first connector is disposed on the first end of the optical fiber and the second connector is disposed on the second end of the optical fiber. The first interrogator is connected to the first connector and includes an optical switch. The optical switch is in optical communication with the first connector of the optical fiber and is configured to selectively block transmission of the optical signal to the optical fiber.

A modular routing node includes a single input port and a plurality of output ports. The modular routing node is arranged to produce a plurality of different deflections and uses small adjustments to compensate for wavelength differences and alignment tolerances in an optical system. An optical device is arranged to receive a multiplex of many optical signals at different wavelengths, to separate the optical signals into at least two groups, and to process at least one of the groups adaptively.

An optical waveguide device comprising: one or more photonic chips, the one or more photonic chips including: a first portion of a photonic chip comprising an array of first components, each of the first components having an optical input and an electrical output; and a second portion of a photonic chip comprising an array of second components, each of the second components configured to receive an electrical input; the optical waveguide device further comprising: an integrated circuit; the integrated circuit forming an electrical bridge between the electrical outputs of the first components and respective electrical inputs of the second components; wherein the integrated circuit is directly mounted onto the one or more photonic chips; and/or wherein the integrated circuit is located between the first portion of a photonic chip and the second portion of a photonic chip.

A modular routing node includes a single input port and a plurality of output ports. The modular routing node is arranged to produce a plurality of different deflections and uses small adjustments to compensate for wavelength differences and alignment tolerances in an optical system. An optical device is arranged to receive a multiplex of many optical signals at different wavelengths, to separate the optical signals into at least two groups, and to process at least one of the groups adaptively.

Aspects of the present disclosure describe large scale steerable optical switched arrays that may be fabricated on a common substrate including many thousands or more emitters that may be arranged in a curved pattern at the focal plane of a lens thereby allowing the directional control of emitted light and selective reception of reflected light suitable for use in imaging, ranging, and sensing applications including accident avoidance.

An integrated photonic device comprises: an input waveguide configured to extend in an input plane, and an output waveguide configured to extend in an output plane, wherein the output plane is parallel to or contained within the input plane; an input coupler optically coupled to the input waveguide, wherein the input coupler is configured to redirect a light signal out of the input waveguide and the input plane; a light property modifier configured to receive the light signal from the input coupler and reflect the light signal towards the output plane, wherein the light property modifier is configured to selectively adjust an optical path length of the light signal; and an output coupler optically coupled to the output waveguide, wherein the output coupler is configured to receive the reflected light signal from the light property modifier and redirect the light signal into the output waveguide and the output plane.

System, methods, and other embodiments described herein relate to a photonic apparatus. The photonic apparatus including a phase alignment waveguide including waveguide inputs and waveguide outputs. The waveguide inputs being operably connected with a light source to provide a light wave into the phase alignment waveguide and the waveguide outputs providing a plurality of light waves from the optical waveguide. The phase alignment waveguide modulates the light wave to generate the plurality of light waves with different phases. The photonic apparatus includes a transmit switch operably connected with the waveguide inputs to selectively connect at least one of the waveguide inputs with the light source to provide the light wave into the phase alignment waveguide. The photonic apparatus includes control circuitry operably connected with the transmit switch, the control circuitry dynamically activating the at least one of the waveguide inputs according to an electronic control signal.

A method in an optical Wavelength Selective Switch, WSS, for multidirectional switching of optical signals. The optical WSS comprises a reflective element, a first tributary port and a second tributary port. The optical WSS switches (304) an optical signal between the first tributary port and the second tributary port with the reflective element.

Provided herein is a depolarizer circuit having an input waveguide configured to receive light from a light source; a splitter configured to provide light from the input waveguide in a first and second polarization states; a first rotator configured to rotate the light from the first polarization state to the second polarization state; a first delay line configured to delay the light in the second polarization state; a coupler configured to couple the rotated and delayed light; a second rotator configured to rotate the coupled light back to the first polarization state; a second delay line configured to delay the coupled light in the second polarization state; and a combiner configured to combine light from second rotator and delay line as depolarized light, where the first and second delay lines provide a phase delay difference therebetween greater than or equal to a coherence of the light source.