Abstract: The invention relates to a splice protection device for spliced optical fibers and to a method particularly for providing an access point to an optical fiber cable in a dwelling unit of a multi dwelling unit. To facilitate mounting of a splice protection device, the splice protection device according to the invention comprises a first and a second tube, the second tube being arranged concentrically and slidable within the first tube, the first and second tubes being adapted to receive at least one spliced fiber. The present invention furthermore relates to a method for providing an access point to a provider optical cable in a dwelling unit of a multi-dwelling unit.

Abstract: An optical waveguide system includes a substrate, a cladding layer arranged on the substrate, a core layer arranged on the cladding layer, and a lens-prism patterned in the core material, the lens-prism comprising a Fresnel lens portion, and a Fresnel prism portion.

Abstract: A process for preparing a subassembly, the process comprising: (a) defining the location of one or more grooves for receiving optical conduits on the top planar surface of a wafer or panel, the grooves corresponding to multiple interposers on the wafer or panel; and (b) etching the grooves into the wafer or panel, each groove having sidewalls and first and second terminal ends and a first facet at each terminal end perpendicular to the side walls, each first facet having a first angle relative to the top planar surface, each groove being shared by a pair of transmitting and receiving interposers on the wafer or panel prior to being diced such that the first and second terminal ends of each groove correspond to transmitting and receiving interposers, respectively.

Abstract: An optical fiber coupling assembly includes a first optical fiber connector, a second optical fiber connector, and a cable. The first optical fiber connector defines a number of first blind holes receiving first focus lenses, and first through holes respectively communicating with the first blind holes. The second optical fiber connector defines a number of second blind holes receiving second focus lenses, and second through holes respectively communicating with the second blind holes. The cable includes a number of optical fibers. Each optical fiber includes a first end and a second end, and the first end is received in a corresponding one of the first through holes and aligned with the a corresponding one of the first focus lenses, and the second end is received in a corresponding one of the second through holes and aligned with a corresponding one of the second focus lenses.

Abstract: An ink including at least one first reactive component, at least one second component comprising a triggerable component, at least one third reactive component, and an optional colorant; wherein the at least one first reactive component and the at least one third reactive component are capable of reacting with one another to form a solid ink on a substrate; wherein the at least one first reactive component is encapsulated in a microcapsule; wherein the ink can be jetted onto a substrate and treated whereby the treatment causes the at least one triggerable component to trigger the rupture of the microcapsule thereby releasing the at least one first reactive component from the microcapsule so that the at least one first reactive component and the at least one third reactive component come into contact, react, and polymerize thereby curing the ink.

Abstract: A method of forming a test pattern in a printer, wherein the printer may include at least one liquid discharge head including a nozzle plate, and the nozzle plate has a plurality of nozzles formed therethrough, wherein the plurality of nozzles are configured to discharge a liquid and are arranged in a plurality of rows which are parallel to each other and extend in a particular direction, the method may comprise the steps of selecting a first nozzle of the plurality of nozzles from a first row of the plurality of rows, selecting a second nozzle of the plurality of nozzles from a second row of the plurality of rows, and discharging the liquid from the first nozzle and from the second nozzle onto a medium, wherein a third row of the plurality of rows is positioned between the first row and the second row.

Abstract: An optical fiber ribbon comprising a plurality of the coated optical fibers 2 arranged in plane and flame-retardant films 4a and 4b to integrate the coated optical fibers 2 is provided. The flame-retardant films 4a and 4b have an adhesive layer 5 formed thereon, and a plurality of the coated optical fibers 2 arranged in plane are integrated by the adhesive layer. The optical fiber ribbon 1 in this constitution uses flame-retardant films, wherein the ribbon thickness can be lowered and separation of single fiber can be facilitated by tearing off the film.

Abstract: Methods, systems, and apparatus, for drop ejection, specifically, for driving drop ejectors using n-type double-diffused metal oxide semiconductor (NDMOS) transistors with sputtered piezoelectric transducers. In general, in one aspect, an apparatus includes a n-type double-diffused metal oxide semiconductor transistor. The apparatus also includes a piezoelectric transducer. A first surface of the piezoelectric transducer is coupled to the n-type double-diffused metal oxide semiconductor transistor. The apparatus also includes a first waveform generator configured to generate an ejector waveform to apply to a second surface of the piezoelectric transducer. The ejector waveform includes at least a positive pulse and a negative pulse. The apparatus also includes a second waveform generator configured to generate a control waveform to apply to the n-type double-diffused metal oxide semiconductor transistor to selectively actuate the piezoelectric transducer.

Abstract: A liquid droplet ejecting apparatus includes a droplet ejection head, an absorber, a moving mechanism, and a controller. The droplet ejection head includes liquid passages having at their leading ends ejection openings which eject droplets, an ejection face which faces a recording medium onto which droplets ejected from the ejection openings are placed, and an actuator which applies energy to liquid inside the liquid passages. The absorber includes a liquid-absorbent facing portion which faces the ejection openings when the absorber faces the ejection face. The moving mechanism moves the droplet ejection head and the absorber relatively to each other such that the droplet ejection head and the absorber are positioned in an absorbing position where the ejection openings and the facing portion face each other.

Abstract: A method of manufacturing an optical path change optical connector, the method including: resin-molding a core part, the core part including an optical-fiber-hole-formed portion having an optical fiber hole, and a positioning structure portion for positioning the core part with respect to the circuit board; inserting an optical fiber into the optical fiber hole; and over-molding the core part with light-transmitting resin, covering a front end face of the optical-fiber-hole-formed portion and forming an inclined internal reflective surface opposite to the front end face of the optical-fiber-hole-formed portion, such that the inclined internal reflective surface is positioned to reflect light between the optical fiber inserted into the optical fiber hole and an optical element disposed on a circuit board on which the core part is mounted.

Abstract: A liquid ejecting apparatus includes a first carriage movement mode, in which a stop position of a carriage in movement of this time is determined to be at a given position in a width direction on the basis of a size in the width direction of a liquid-ejected medium, and a second carriage movement mode, in which the stop position of the carriage in the movement of this time is determined on the basis of at least one of the liquid ejection data in the movement of this time or the liquid ejection data in the movement of the next time, and liquid ejection is carried out with one of the first carriage movement mode and the second carriage movement mode selected in accordance with the type of liquid-ejected medium.

Abstract: The invention is an optical element for limiting the propagation of light in oblique directions with respect to the optical element surface, and includes: a transparent substrate and a light ray control layer formed on a flat surface of said transparent substrate, wherein the light ray control layer has a transparent portion and a light absorbing portion, the transparent portion has a plurality of independent pattern elements having an identical configuration separated by said light absorbing portion and arranged at intervals.

Abstract: Provided is an optical device. The optical device includes a substrate having a waveguide region and a mounting region, a planar lightwave circuit (PLC) waveguide including a lower-clad layer and an upper-clad layer on the waveguide region of the substrate and a platform core between the lower-clad layer and the upper-clad layer, a terrace defined by etching the lower-clad layer on the mounting region of the substrate, the terrace including an interlocking part, an optical active chip mounted on the mounting region of the substrate, the optical active chip including a chip core therein, and a chip alignment mark disposed on a mounting surface of the optical active chip. The optical active chip is aligned by interlocking between the interlocking part of the terrace and the chip alignment mark of the optical active chip and mounted on the mounting region.

Abstract: A fiber optic cable fixture 1 has a joint member 3, a swaging member 4, and a fastening member 5. The joint member 3 has a cylindrical shape in which a through hole 10 is formed and includes a joint section 11 joined to another member, a male screw 12, and a cylindrical section 13 that is smaller in diameter than the male screw 12 and that is covered with a jacket 7 and tension fibers. The swaging member 4 is fitted to the cylindrical section 13 while covered with the jacket 7. A female screw 16 is formed at one end of an inner peripheral surface of the fastening member 5. A tapered surface 17 is formed on another end of the inner peripheral surface of the fastening member 5.

Abstract: A wet on wet garment printing device for printing on a textile surface comprises: an ink holder; a printing head mounted for printing onto the textile surface using ink from the ink holder; a wetting applicator for wetting the locations prior to printing using a wetting composition; and an ink regulator configured to identify compatibility of ink in the holding unit with the wetting composition and to operate the wetting applicator only upon successful identification of compatibility.

Abstract: Cables have reduced freespace, reduced tube diameters, and reduced strength member diameters. The cables are designed to pass robustness testing such as GR-20 while using smaller amounts of raw materials to produce.

Abstract: Novel integrated electro-optic structures such as modulators and switches and methods for fabrication of the same are disclosed in a variety of embodiments. In an illustrative embodiment, a device includes a substrate with a waveguide and an optical resonator comprising polycrystalline silicon positioned on the substrate. First and second doped semiconducting regions also comprise polycrystalline silicon and are positioned proximate to the first optical resonator. The first optical resonator is communicatively coupled to the waveguide.

Abstract: An optical waveguide system includes a substrate, a cladding layer arranged on the substrate, a core layer arranged on the cladding layer, a lens patterned in the core material, and a prism patterned in the core material, the prism arranged adjacent to the lens.

Abstract: Embodiments are disclosed that relate to fabrication of a laminated optical wedge. One embodiment provides a method comprising inserting a wedge blank into a vacuum molding tool, applying a vacuum to the vacuum molding tool, and removing a layer from a top surface of the wedge blank to expose a machined surface of the wedge blank. The method further comprises laminating a finish piece to the machined surface via an adhesive, wherein the finish piece comprises a smoother surface than the machined surface, and curing the adhesive to form a finished optical wedge. The method further comprises removing the finished optical wedge from the vacuum molding tool.

Abstract: A lighting device at least has: a plurality of light emitting elements that emit light by a forward direction current; a direct-current power supply; a first wiring and a second wiring for supplying electrical power to the plurality of light emitting elements from the direct-current power supply; and a switch for switching the polarity of the electrical power to be supplied to the first wiring and the second wiring; in which the plurality of light emitting elements include forward direction connection in which the forward direction current flows when the electrical power having a positive polarity is applied to the first wiring and reverse direction connection in which the forward direction current flows when the electrical power having a positive polarity is applied to the second wiring and being connected between the first wiring and the second wiring.