Abstract: An optical control device is provided which can suppress crosstalk between electrodes without increasing the entire size of the device itself. The optical control device includes a substrate having an electro-optical effect, an optical waveguide formed in the substrate, and a modulation electrode modulating optical waves propagating in the optical waveguide. The modulation electrode includes at least two signal electrodes and ground electrodes arranged to interpose the signal electrodes therebetween. The optical control device further includes an electrical connection member that electrically connects the ground electrode disposed between the two signal electrodes to other ground electrodes and that is disposed to cross over part of the signal electrode.

Abstract: Embodiments of forming a waveguide structure are provided. The waveguide structure includes a substrate, and the substrate has an interconnection region and a waveguide region. The waveguide structure also includes a trench formed in the substrate, and the trench has a sloping sidewall surface and a substantially flat bottom. The waveguide structure further includes a bottom cladding layer formed on the substrate, and the bottom cladding layer extends from the interconnection region to the waveguide region, and the bottom cladding layer acts as an insulating layer in the interconnection region. The waveguide structure further includes a metal layer formed on the bottom cladding layer on the sloping sidewall surface.

Abstract: A demarcation device is disclosed. The demarcation device mounts on top of a cable tray. When mounted on the to of a cable tray the demarcation device is above a length of the cable tray and the bottom edge of the demarcation device is parallel with a top edge of the cable tray and a cable path in the cable tray remains un-obstructed.

Abstract: The specification describes multimode optical fibers with specific design parameters, i.e., controlled refractive index design ratios and dimensions, which render the optical fibers largely immune to moderately severe bends. The modal structure in the optical fibers is also largely unaffected by bending, thus leaving the optical fiber bandwidth essentially unimpaired. Bend performance results were established by DMD measurements of fibers wound on mandrels vs. measurements of fibers with no severe bends. Additional embodiments of the present invention describe an improved optical link when the inventive multimode fiber is connected to standard or conventional multimode fibers.

Abstract: Disclosed method and apparatus embodiments provide a photonic device with optical isolation from a supporting substrate. A generally rectangular cavity in cross section is provided below an element of the photonic device and the element may be formed from a ledge of the supporting substrate which is over the cavity.

Abstract: An optical modulator includes a package that accommodates therein a first substrate and a second substrate different from the first substrate, and outside the package, a flexible circuit board. The first substrate has plural optical modulating units disposed thereon in parallel and each including a Mach-Zehnder optical waveguide. Plural first signal line paths corresponding to the optical modulating units are disposed on the second substrate. Plural second signal line paths corresponding to the optical modulating units are disposed on the flexible circuit board. Electrical lengths of the second signal line paths are different from one another. Electrical lengths of signal paths that span from input ends of the second signal line paths corresponding to the optical modulating units to base points on signal electrodes, via the first signal line paths, are equal to one another.

Abstract: An optical fiber assembly including an optical fiber ribbon and an optical connector is provided. The optical fiber ribbon includes a ribbon matrix, a first group of optical fibers embedded in the ribbon matrix, a second group of optical fibers embedded in the ribbon matrix, and a split in the ribbon matrix at a first end of the ribbon forming a space between a first end of the first group of optical fibers and a first end of the second group of optical fibers. The optical connector includes a body, a first array of openings defined in the body, and a second array of openings defined in the body. The second array is spaced from the first array. The bond between the ribbon matrix and the optical fibers prevents elongation of the split.

Abstract: Disclosed is a system and method of combining optical interference cancellation with other methods of interference cancellation, including electronic cancellation, digital filtering, and beam steering algorithms, to remove co-located interference, remote interference of an unknown origin, and multipath interference components created by reflections of signals both known and unknown.

Abstract: An opto-electric (OE) module having a front and back orientation and comprising a connector having a front end configured to mate with a connector, an optical interconnect comprising an optical conduit with first and second ends, the first end being terminated by at least one first ferrule, the first ferrule being disposed in the connector in a non-biased state, and the second end being optically coupled to at least one opto-electric device (OED), wherein the optical interconnect is not configured to bend to accommodate distance variations between said first ferrule and said OED, a cover being attached to the connector and having an interior, a circuit board disposed in the interior and having an electrical interface configured to connect to a daughter card, and the opto-electric device (OED) attached to the circuit board and optically connected to the second end.

Abstract: An optical connector for optically connecting at least one light source to at least one light receiver is disclosed. The optical connector includes first and second connector members respectively having first and second positive-power lens elements with respective first and second planar lens surfaces. The lens elements are arranged in their respective connector members such that when the two connector members are operably mated, the first and second lenses form an optical system where the first and second planar lens surfaces are spaced apart in opposition with a narrow gap in between, and are non-perpendicular to the optical system axis. The lenses may be conventional uniform-refractive-index lenses having a convex surface or may be gradient-index lenses having two planar surfaces. The optical connector is tolerant to contamination that can find its way into the narrow gap.

Abstract: A novel, hybrid optical fiber stub device comprises a first ferrule transparent to UV light and a second ferrule including a conventional material. An optical fiber is disposed through the first ferrule and second ferrule. The input and output faces of the optical fiber are prepared suitable for optical coupling. A photonic device is coupled to the first optical fiber surface. A UV curable epoxy is disposed between the photonic device and the first optical fiber surface. The UV curable epoxy includes an index of refraction between an index of refraction of the first optical fiber and an index of refraction of the photonic device. A second optical fiber is coupled to the first optical fiber.

Abstract: An optical device includes an optical bench and two flip-chip bonded optical chips. The optical bench includes a large area slab waveguide structure which has an input facet facing the first optical chip, an output facet facing the second optical chip, and one or more curved facet which reflects the slab mode light such that the input optical mode coupled through the input facet diverges in the slab waveguide plane as it propagates, reflects at the one or more curved facets, and focuses to an output optical mode at the output facet with mode size larger than the input optical mode in the in-plane direction. During fabrication, after the first optical chip is flip-chip bonded, the location of the focused output optical mode on the output facet is determined, and then the second optical chip is flip-chip bonded based on the determined location of the output optical mode.

Abstract: A structure includes a channel waveguide and a pocket adjacent to an input facet of the channel waveguide. A laser having an output facet is positioned in the pocket. The structure includes a stop on either the laser or a wall of the pocket. The stop is positioned at an interface between the laser and the wall of the pocket such that the output facet of the laser and the input facet of the waveguide are separated by a gap.

Abstract: An attachable optical component is aligned with a base optical component. The attachable optical component has a mounting surface interfacing with the base optical component and an exposed surface opposed to the mounting surface. Laser light is directed to the exposed surface of the attachable optical component for delivery to the mounting surface. The attachable optical component guides and homogenizes the laser light delivered to the mounting surface and uniformly heats a bonding feature between the mounting surface and the base optical component.

Abstract: An organizer for an optical fiber cable has at least two loop retaining sections (16; 33) facing each other with a predetermined distance such that a loop (10) of the optical fiber cable (12) is restrained between the loop retaining sections (16; 33) by an elastic resetting force of the looped optical fiber cable (10). Certain types of organizers are removably mounted to a base to be free-standing.

Abstract: A cable exit trough is mountable to a lateral trough section either during initial assembly of the cable routing system, or at a later date. The exit trough includes a bracket portion mountable to the top edge of one of the sides of the lateral trough section. Two lead-ins are provided to lead the cable in an upward direction from the lateral trough section to the exit trough. The exit trough includes an exit trough portion extending from the bracket portion upwardly away from the lateral trough section. The exit trough portion includes a convexly curved bottom trough surface, and two convexly curved upstanding sides. The exit trough portion and the lead-ins define a cable pathway from the lateral trough section to an exit point of the exit trough portion which can either lead downwardly relative to the lateral trough section, or horizontally.

Abstract: The present invention provides an optical waveguide excellent in all of transparency, a bending property and heat resistance and a dry film for manufacturing an optical waveguide. A clad layer of the optical waveguide according to the present invention is formed by using a dry film containing a polymer comprising at least a (meth)acrylate monomer with an epoxy group and a (meth)acrylate monomer without an epoxy group; and cationic or anionic curing initiator.

Abstract: An apparatus for performing a measurement of a downhole property includes an optical fiber having a first section that has a first set of fiber Bragg gratings with a first resonant wavelength inscribed therein and a second section that has a second set of fiber Bragg gratings with a second resonant wavelength different from the first resonant wavelength inscribed therein. The second section is in series with the first section. An optical interrogator emits a swept-wavelength frequency domain light signal having varying wavelength amplitude modulation into the optical fiber, receives a frequency domain return light signal, and transforms the frequency domain return signal into a time domain to determine a resonant wavelength shift of each fiber Bragg grating and the corresponding location of each interrogated fiber Bragg grating. A processor converts the resonant wavelength shift of each interrogated fiber Bragg grating into the downhole property measurement.

Abstract: A portion on the light exit end surface side of a fiber optic plate includes a first portion and a second portion. The first portion corresponds to a peripheral portion of a semiconductor photodetecting element. The second portion corresponds to a thin portion of the semiconductor photodetecting element and projects more toward the semiconductor photodetecting element than the first portion. A height of a step made between the first portion and the second portion of the fiber optic plate is lower than a height of a step made between the thin portion and the peripheral portion of the semiconductor photodetecting element. The semiconductor photodetecting element and the fiber optic plate are fixed by a resin, in a state in which the first portion and the peripheral portion are in contact and in which the second portion and the thin portion are separated.

Abstract: A liquid-discharging head includes a substrate; a flow passage wall-forming layer bonded to the substrate so as to form a flow passage for liquid between the substrate and the flow passage wall-forming layer, the flow passage communicating with a discharge port configured to discharge the liquid; an element configured to generate energy used for discharging the liquid from the discharge port and provided on the flow passage wall-forming layer; a metal layer provided with the discharge port so as to correspond to the element; and a projecting portion made of a metal and extending from the metal layer through the flow passage wall-forming layer and projecting in the direction of the substrate.