Abstract: An optical transmitter-receiver assembly includes an optical transmitter-receiver device coupled via first optical fiber to optical splitter, plurality of second optical fibers each having a first end and a second end. The first ends is coupled to the optical splitter, the second ends are respectively coupled to plurality of optical connectors. The optical transmitter-receiver device includes main body and rubber sleeve. Space in the main body is divided into top portion and bottom portion by partition. Receiver is disposed in the top portion and coupled via fiber array to the first optical fiber. The receiver coupled via amplifier to flexible circuit board. Plurality of coaxial lasers is disposed in the bottom portion. Each of the plurality of coaxial lasers has an emitting end coupled to the first fiber, and the plurality of coaxial lasers coupled via inflexible circuit board to flexible circuit board.

Abstract: A cell site includes a tower, a multi-service terminal mounted to the tower and a base transceiver station in communication with the multi-service terminal. The multi-service terminal includes a housing and a plurality of adapters mounted to the housing. Each of the adapters includes an outer port accessible from outside the housing and an inner port accessible from inside the housing.

Abstract: Disclosed are interposer structures having an optical fiber connection and a related fiber optic ferrule that can form a portion of an optical assembly. The interposer structure is useful for transmitting optical signals to/from an integrated circuit that may be attached to the interposer. Specifically, the interposer structure and the related ferrule of the optical connector provide a passively aligned structure having a matched thermal response to maintain a suitable optical connection between the devices over a range of temperatures.

Abstract: An electrical discharge, suitable for heating optical fibers for processing, is made in a controlled partial vacuum, such that saturation of available ionizable gas molecules is reached. The workpiece temperature is thereby made to be a stably controlled function of the absolute air pressure and is insensitive to other conditions. A system and method accomplishing the foregoing are provided.

Abstract: A fiber optic connector includes a ferrule, a ferrule holder from which the ferrule extends, a housing in which the ferrule holder is received, and a connector body coupled to the housing. The connector body is configured to retain the ferrule holder within the housing. The fiber optic connector further includes a strain relief assembly comprising a support coupled to a rear portion of the connector body and a boot received over support. The support includes a first portion defining a front end of the support and a second portion defining a back end of the support, with the second portion having a stiffness less than the first portion. Additionally, the support and boot are formed from respective first and second materials, with the second material being less rigid than the first material.

Abstract: Various optical isolators are disclosed. One embodiment provides an optical isolator comprising a waveguide that includes polymer magneto-optical media. In a particular embodiment, the waveguide is dimensioned for single mode operation in the selected isolation range. A cross-section of the waveguide is inhomogeneous in terms of magneto-optical materials. Polymer magneto-optical material is a part of the optical waveguide structure. The inhomogeneity induces the propagation constant shift, which is propagation-direction-dependent. An embodiment is characterized by a cutoff frequency for forward propagating waves that is different than the cutoff frequency for reverse waves; the dimensions and direction of magnetization of the waveguide can be tailored so that, in a particular embodiment, the cutoff frequency for forward propagating waves is lower than the cutoff frequency for reverse waves.

Abstract: A method for installing a drop terminal includes providing a drop terminal assembly including a drop terminal having an exterior surface, a first cable spool engaged to the exterior surface of the drop terminal, a second cable spool engaged to the first cable spool and a fiber optic cable having a first length disposed about the first cable spool and a second length disposed about the second cable spool. The drop terminal assembly is rotated to deploy the second length of fiber optic cable. The second cable spool is removed. The first length of fiber optic cable is bundled. The bundled first length of fiber optic cable is removed from the first cable spool. The drop terminal is removed from the first cable spool. The drop terminal is mounted to a structure.

Abstract: The disclosure provides for writing or introducing waveguide-like structures in transparent polycrystalline ceramics using femtosecond laser pulses. The disclosure further provides for tuning the demarcation of the waveguide-like structures by varying the number of incident pulses per unit area.

Abstract: An optical module includes: a substrate; a wiring pattern; and a cover material. The wiring pattern includes, on the substrate, an electrode portion having a predetermined width and a signal line having a width smaller than the predetermined width and connected to the electrode portion. The cover material covers a part of the electrode portion and the signal line.

Abstract: An optical fiber cable has a sectional area of Ac [?m2] and housing a number N of optical fibers. A transmission loss ?dB [dB/km], a mode field diameter W [?m], an effective area Aeff [?m2], an effective length Leff [km], and a wavelength dispersion D [ps/nm/km] of each of the optical fibers at a wavelength of 1550 nm satisfy a predetermined equation.

Abstract: A method is disclosed to provide improved fiber inline optical power monitoring that eliminates the need for micro-bending the fiber or for fabricating micro-reflector on the fiber. A subset of light is tapped through an offset at a fusion-spliced upstream and downstream optic fiber, and is guided out of the downstream fiber by a light guide to a reflector and photo-sensing measurement. The disclosed inline fiber monitoring is thus cost effective, wavelength independence, reliable, stable, and also causes less light transmission loss.

Abstract: There is provided a method for producing a low-loss alkali metal-doped silica core optical fiber having excellent hydrogen resistance. The method for producing the optical fiber according to the present invention includes a drawing step of drawing an optical fiber preform in a drawing furnace to produce a silica glass-based optical fiber including a core region containing an alkali metal with an average concentration of 0.5 atomic ppm or more and a cladding region that surrounds the core region and a heating step of heating the optical fiber in a heating furnace through which the optical fiber drawn from the drawing furnace passes.

Abstract: [Task] Reduction in crosstalk between signal electrodes. [Means for Resolution] An optical modulator 1 includes a relay substrate 3 including a substrate portion 30, and signal electrodes 31 and 32, and a ground electrode 33 which are provided on the substrate portion 30, and an optical waveguide substrate 4 including an electrode-optical substrate 40, signal electrodes 431 and 432, and an optical waveguide 42 which are provided on the electro-optical substrate 40.

Abstract: A fiber optic enclosure includes a housing including a base and a cover that cooperatively define an interior region of the housing; and a cable spool assembly rotatably disposed in the interior region of the housing. The cable spool includes a drum portion; and a tray assembly engaged to the drum portion and configured to rotate in unison with the drum portion when the cable spool assembly is rotated relative to the base. The tray assembly includes at least a first tray. Each tray includes optical adapters disposed in a row along a first end of the tray. Certain types of trays are pivotal relative to the drum portion along a pivot axis extending generally parallel to the row of adapters along a second end of the tray opposite the first end. Other types of trays include a second row of optical adapters that pivot relative to the first row.

Abstract: Fiber optic cable sub-assemblies having a fiber optic cable including at least one optical fiber attached to a circuit board are disclosed. The circuit board includes an active optical component in operable communication with the optical fiber for forming an active optical cable (AOC) assembly. A strain relief device attaches an end portion of the fiber optic cable to the circuit board, thereby forming the cable sub-assembly. Methods of assembling the fiber optic cable sub-assembly are also disclosed and include the step of attaching an end portion of the fiber optic cable to the circuit board.

Abstract: A multi-chip module (MCM) is described. This MCM includes two substrates that are passively self-assembled on another substrate using hydrophilic and hydrophobic materials on facing surfaces of the substrates and liquid surface tension as the restoring force. In particular, regions with a hydrophilic material on the two substrates overlap regions with the hydrophilic material on the other substrate. These regions on the other substrate may be surrounded by a region with a hydrophobic material. In addition, spacers on a surface of at least one of the two substrates may align optical waveguides disposed on the two substrates, so that the optical waveguides are coplanar. This fabrication technique may allow low-loss hybrid optical sources to be fabricated by edge coupling the two substrates. For example, a first of the two substrates may be a III/V compound semiconductor and a second of the two substrates may be a silicon-on-insulator photonic chip.

Abstract: Debris-removing cap includes a cap body having a receiving cavity and an interior surface disposed within the receiving cavity. The cap body is configured to be attached to an optical device such that a mating face of the optical device is disposed within the receiving cavity. The interior surface is configured to face the mating face of the optical device. The debris-removing cap also includes a lens wiper that is coupled to the interior surface within the receiving cavity and extends away from the interior surface toward the mating face of the optical device. The lens wiper moves relative to the mating face when activated by a user of the debris-removing cap. The lens wiper engages a lens of the mating face when activated by the user to remove debris from the lens.

Abstract: In an optical waveguide having plural cores including a pair of adjacent cores with an identical core structure, a minimum value D of center-center distance between the adjacent cores is 15 ?m to 60 ?m, each of the plural cores has a bent portion fixed in a radius of curvature Rb of not more than 7 mm, a bend supplementary angle of the bent portion is 58° to 90°, a height of the optical waveguide is defined as a height of not more than 10 mm, and a crosstalk of the adjacent cores is not more than 0.01.

Abstract: An assembling device for assembling optical fibers in the main body includes a support member and a blocking member. The support member includes a top surface. The top surface defines a receiving cavity and a supporting recess communicating with the receiving room. The blocking member includes a blocking surface. The blocking member is partially received in the receiving cavity. The blocking surface is exposed in the supporting recess. The supporting recess is configured for supporting the main body and contacting distal ends of the optical fibers.

Abstract: A semiconductor laser element includes: a semiconductor-layered structure including a waveguide core layer and having a distributed feedback laser portion and a distributed Bragg reflection portion, the waveguide core layer having a length continuous in an optical cavity length direction and a diffraction grating layer being disposed in vicinity of the waveguide core layer and along the waveguide core layer in the distributed feedback laser portion, and the waveguide core layer being disposed discretely and periodically to form a diffraction grating in the distributed Bragg reflection portion; and an electrode for injecting a current to the distributed feedback laser portion. The distributed feedback laser portion oscillates a laser light at a wavelength corresponding to a period of the diffraction grating layer. The diffraction grating formed by the waveguide core layer in the distributed Bragg reflection portion is set to have a stop band including the wavelength of the laser light.