Abstract: The present disclosure relates to a hardened power and optical connection system for use with hybrid cables. The hardened power and optical connection system includes electrical pin and socket contacts for providing power connections, and ferrules for providing optical connections. The hardened power and optical connection system has an integrated fiber alignment provided through a mating relationship between a plug and a socket.

Abstract: The disclosure relates to wavelength-controlled directivity of all-dielectric optical nanoantennas. One example embodiment is an optical nanoantenna for directionally scattering light in a visible or a near-infrared spectral range. The optical nanoantenna includes a substrate. The optical nanoantenna also includes an antenna structure disposed on the substrate. The antenna structure includes a dielectric material having a refractive index that is higher than a refractive index of the substrate and a refractive index of a surrounding medium. The antenna structure includes a structure having two distinct end portions. The antenna structure is asymmetric with respect to at least one mirror reflection in a plane that is orthogonal to a plane of the substrate.

Abstract: A rack system comprising a plurality of removable housing modules each configured to hold a plurality of electronic modules in stepped rows, with the housing modules being arranged on a tray at least partly within a housing in a dense configuration, thereby providing ease of access to the electronic modules for routing wire connectors to each of the electronic modules in an organized manner.

Abstract: A method for forming an optical fiber preform and fibers drawn from the preform. The method includes forming a soot cladding monolith, inserting a consolidated core cane into the internal cavity, and processing the resulting core-cladding assembly to form a preform. Processing may include exposing the core-cladding assembly to a drying agent and/or dopant precursor, and sintering the core-cladding assembly in the presence of a reducing agent to densify the soot cladding monolith onto the core cane to form a preform. The preform features low hydroxyl content and low sensitivity to hydrogen. Fibers drawn from the preform exhibit low attenuation losses from absorption by the broad band centered near 1380 nm.

Abstract: An optical interconnection device including: a first element layer formed on a substrate; a second element layer disposed on the first element layer and receiving an optical signal; and a mode converter interposed between the first element layer and the second element layer, and eliminating a difference between an effective refractive index of the first element layer and an effective refractive index of the second element layer and match a mode profile, wherein the first element layer, the mode converter, and the second element layer are sequentially disposed on respective planes spaced apart from each other on the substrate, and one end of the mode converter overlaps a part of the second element layer, and the other end of the mode converter overlaps a part of the first element layer.

Abstract: A system for conversion or amplification using quasi-phase matched nonlinear optical wave-mixing includes a first radiation source for providing a pump radiation beam, a second radiation source for providing a signal radiation beam, a bent structure for receiving the pump radiation beam and the signal radiation beam, and an outcoupling radiation propagation portion for coupling out an idler radiation beam generated in the bent structure. A radiation propagation portion of the bent structure is made of a uniform three-dimensional material at least partly covered by a two-dimensional or quasi-two-dimensional material layer and has a dimension taking into account the spatial variation of the nonlinear optical susceptibility along the radiation propagation portion as experienced by radiation traveling along the bent structure for obtaining quasi-phase matched nonlinear optical wave-mixing in the radiation propagation portion.

Abstract: An optical line card includes a plurality of coherent receivers and a plurality of optical modulators. The coherent receivers are each configured to receive a corresponding channel of a received optical superchannel. The optical modulators are each configured transmit a corresponding channel of a transmitted optical superchannel. Each of a plurality of optical splitters is configured to receive a corresponding one of a plurality of unmodulated optical signals from an optical source external to the line card. Each splitter directs a first portion of light received by that splitter to a corresponding one of the coherent receivers, and a second portion of light received by that splitter to a corresponding one of said optical modulators.

Abstract: The present invention discloses a fiber optic connector comprises: a ferrule assembly; a spring seat provided behind the ferrule assembly; and a spring provided between the ferrule assembly and the spring seat. The spring seat has a receiving chamber having an insertion port through which a portion of the ferrule assembly is inserted into the receiving chamber; wherein the ferrule assembly is pre-assembled into the receiving chamber of the spring seat in a way that the ferrule assembly is held to be movably engaged with the spring seat. The spring is fitted and compressed in the receiving chamber. As a result, the ferrule assembly, the spring seat and the spring are pre-assembled into an integral assembly before being inserting into a connector housing. All components of the connector except for the housing may be smoothly pulled through a small long pipe as a whole.

Abstract: A method and a system for nonlinear optical interaction in a nonlinear medium, comprising interacting at least one input beam in a nonlinear medium located at a spectrally dispersed plane. The method and system allows generating output photons from input photons, the output photons having properties that linearly depend on the properties of the input photons and that are mutually independent, comprising interacting the input photons in a nonlinear medium located at a spectrally dispersed plane.

Abstract: A unitary fiber optic ferrule reflects light off an interior lens and through the fiber optic ferrule. Optical fibers can be easily secured in the unitary fiber optic ferrule. An adapter to secure the unitary fiber optic ferrule to a optical component assembly is also presented. The adapter provides a sealing function for the lenses and to provide routing for optical fibers from other assemblies of unitary fiber optic ferrules and adapters.

Abstract: Embodiments of the present disclosure provide techniques and configurations for a rack assembly. In one embodiment, a tray to be disposed in a rack assembly may comprise a plurality of sleds with individual sleds including one or more compute nodes; and a networking element coupled with a sled of the plurality of sleds and configured to communicatively connect the sled to one or more other components of the rack assembly via an optical communication system. The optical communication system may include an external optical cable configured to communicatively connect the networking element with the rack assembly. Other embodiments may be described and/or claimed.

Abstract: In a terahertz wave generation apparatus including a first non-linear optical crystal 3 on which first laser L1 and second laser L2 from laser generation means 2 are incident to generate terahertz wave TH1, the laser generation means includes a second non-linear optical crystal 7 on which laser having the same wavelength as that of the second laser is incident to generate idler light L1 including a plurality of wavelengths, and makes the idler light L1 generated from the second non-linear optical crystal incident on the first non-linear optical crystal as the first laser L1, to generate terahertz wave including a plurality of wavelengths from the first non-linear optical crystal 3, and wavelength selection means including a transmission section which transmits an idler light having the specific wavelength in the idler light including the plurality of wavelengths can be provided, as needed.

Abstract: An optical connector of the disclosure includes: an optical connector body including a housing that houses a ferrule, and a coupling that is movable relative to the housing, the optical connector body being employed to release a latched state by moving the coupling rearward relative to the housing; and a pull member including a pull operation part that is located rearward of the coupling. The pull member includes a pair of side plate parts to be respectively arranged along the side surfaces of the coupling. Each side plate part includes an inner projection that projects inward from an inner surface. The coupling includes a recessed engagement part. The inner projection of the pull member engages with the engagement part of the coupling. When the pull operation part of the pull member is pulled rearward, the coupling is moved rearward relative to the housing by the inner projection of the pull member.

Abstract: An assembly including a pallet, a carousel mounted on the pallet, a plurality of tray assemblies stacked one on top of the other on the carousel. Each of the tray assemblies include a tray body, at least one fiber optic adapter supported at a top side of the tray body and a first spool mounted beneath the tray body. The first spool has spaced-apart flanges and fiber optic cable wrapped about the first spool at a location between the spaced-apart flanges. At least some of the flanges of the first spools of adjacent tray assemblies are coupled together.

Abstract: The cleaning nozzle is used for cleaning an optical fiber connector using a cleaning fluid. The optical fiber connector includes a connector housing. A ferrule is supported within the interior of the connector housing. The nozzle has inner and outer housing members that respectively define an inner channel and an outer channel. The inner channel is sized to accommodate a front-end section of the ferrule. The inner and outer channels are in fluid communication through the interior of the connector housing when the front-end section of the ferrule resides within the inner channel. The nozzle assembly includes the nozzle and the optical fiber connector. Methods of cleaning the interior of the optical fiber connector as well as the ferrule end face, the optical fiber end face and the ferrule outer surface are also disclosed.

Abstract: A hermetic optical subassembly includes an optical bench having a mirror directing optical signals to/from an optical waveguide, a carrier supporting a photonic device, and an intermediate optical bench having a mirror directing optical signals between the photonic device and the optical bench. The optical bench and the intermediate optical bench optically aligns the photonic device to the waveguide along a desired optical path. In one embodiment, the photonic device is an edge emitting laser (EML). The mirror of the optical bench may be passively aligned with the mirror of the intermediate optical bench. The assembled components are hermetically sealed. The body of the optical benches are preferably formed by stamping a malleable metal material to form precise geometries and surface features. In a further aspect, the hermetic optical subassembly integrates a multiplexer/demultiplexer, for directing optical signals between a single optical fiber and a plurality of photonic devices.

Abstract: The invention relates to a module that can be inserted into a housing of an industrial plug-in connector (5), into which module (1) at least one optical fiber connector (2) can be inserted and at least one adapter (3) can be inserted into the module (1), which adapter is connected to the optical fiber connector (2), wherein the adapter (3) contains an optical imaging element (11). In the plugged-in condition, the optical elements (11, 11?), for example the ball lenses proposed above, of two modules (1) are aligned with each other in such a way that the light signal exiting from the optical element (11) of the module of the first industrial plug-in connector (5) is coupled into the optical element (11?) of the module (1?) of the second industrial plug-in connector (5?).

Abstract: Systems and methods implementing a stack on a substrate, where the stack includes a plurality of films structured as layers to convert radiation incident to the stack to radiation of a nonlinear optical signal different from the incident radiation or to a harmonic of the incident radiation, can be used in a variety of applications. The stack can be structured having parameters selected with respect to conversion efficiency and bandwidth the converted radiation. Additional systems and methods can be used in a variety of applications.

Abstract: An optical fiber cable-equipped connector that is electrically connectable to a mating electrical connector; the optical fiber cable-equipped connector comprises a conversion element, to which a cable-side optical fiber core exposed from the end of an optical fiber cable is connected and which converts optical signals and electrical signals, and a circuit board that is electrically connected to the conversion element; the conversion element comprises a conversion element-side optical fiber core, to which the cable-side optical fiber core is connected; the opto-electrical conversion connector comprises the conversion element-side optical fiber core disposed on the mounting face of the circuit board, and an optical fiber connection support that supports the connected portion with the conversion element-side optical fiber core and the cable-side optical fiber core; and the optical fiber connection support comprises the alignment support that supports and aligns the conversion element-side optical fiber core and

Abstract: An optical adapter includes: a housing having a plurality of openings on each of opposite end surfaces thereof; a plurality of ports formed in parallel with each other inside the housing and each extending to form one of the openings on each of the opposite ends surfaces, an optical connector being inserted into each of the openings; and a shutter part installed at each of the ports such that when the optical connector is inserted into an opening of one end of the port, the shutter part leans back to a retreat position that passes light emitted from the optical connector inserted into an opening of another end of the port, when the optical connector is pulled out of the opening of the one end of the port, the shutter part is raised up from the retreat position to a blocking position that blocks the emitted light.