Abstract: An optical receiver for coherent optical communication, includes: a splitting element that splits a signal light into two optical axes; optical hybrids each of which is coupled with the two split optical axes; a skew adjustment element that is arranged on one of the optical axes, and adjusts a difference between optical path lengths of the two optical axes between the splitting element and the optical hybrids; a carrier; an adhesive that is filled between the skew adjustment element and the carrier; and a void that is located at an end portion of an optical axis direction of the skew adjustment element in a region where the skew adjustment element and the carrier are opposed to each other, the void being not filled up with the adhesive.

Abstract: An optical-electric converting module includes a printed circuit board (PCB) and an optical-electric coupling element. The PCB includes a supporting surface, at least one laser diode, and at least one photo diode. The at least one laser diode and the at least one photo diode are positioned on the supporting surface and electrically connected to the PCB. The supporting surface defines at least one locating hole. The optical-electric coupling element includes a lower surface facing the supporting surface. The optical-electric coupling element defines a first cavity in the lower surface. The optical-electric coupling element includes at least one locating pole extending from the lower surface. The optical-electric coupling element is detachably connected to the supporting surface through the engagement of the at least one locating pole and the least one first locating hole, with each laser diode and each photo diode being received in the first cavity.

Abstract: An optical element for installation in a laser processing machine has a surface that is optically unused and/or not subject to a laser beam during operation of the laser processing machine when the optical element is installed in the laser processing machine, and a transponder disposed in a region on or near the surface and containing readable information relating to the optical element.

Abstract: An optical surgical probe includes a handpiece having a metal cannula at a distal end, a light guide within the metal cannula that carries a light beam from a light source through the metal cannula, and a multi-spot generator formed within a distal opening of the metal cannula that seals the distal opening of the metal cannula. The multi-spot generator includes a proximally-facing faceted end surface spaced from a distal end of the light guide that includes at least one facet oblique to a path of the light beam and a ball lens located distal to the faceted end surface. A high-conductivity ferrule surrounds the distal end of the light guide, is in thermal contact with the metal cannula, and includes a side-shield portion extending beyond the distal end of the light guide. The ferrule shields the cannula from a portion of the light beam reflected by the faceted end surface.

Abstract: An optical coupling element of the invention includes: a plurality of incident surfaces having a predetermined curvature, where light emitted from a plurality of light-emitting elements is respectively incident; a reflective surface reflecting the light incident respectively on the incident surfaces and having a predetermined curvature; and a plurality of output surfaces respectively outputting the light reflected by the reflective surface toward an end face of an optical fiber and having a predetermined curvature. The curvatures for the incident surfaces, the reflective surface, and the output surfaces are adjusted such that the X-direction tolerance is greater than the Y-direction tolerance. Here, the alignment direction of the plurality of incident surfaces is the X direction, the advancement direction of the light is the Z direction, and the direction perpendicular to the X and Z directions is the Y direction.

Abstract: An optical module (100) set on a substrate for assembling with a fiber (72) and comprises a light signal gathering device (8), a plurality of electrical contacts (2) set on the light signal gathering device (8) and an optoelectronic device (4) soldered to the electrical contacts (2) for receiving the light signals refocused by the light signal gathering device (8) and transferring the light signals to electrical signals, the light signal gathering device (8) includes a resin body (1) and a light signal gathering portion set on the resin body (1) for refocusing light signals.

Abstract: A method of free space fiber-to-fiber coupling includes providing a first optical fiber and a second optical fiber spaced apart from one another by a free space distance having a pair of spaced-apart achromatic collimating lenses within the free space distance. Essentially single mode light is launched from the first fiber at a wavelength ? or a range of ?s that provides at least a portion of its light at wavelength(s) below a cut-off wavelength for the first fiber. The first optical fiber and second optical fiber are both <50 m and sufficiently short to provide essentially single mode operation. The essentially single mode light after the launching propagates as free space light through said free space distance and is received by and propagates in the second optical fiber as essentially single mode light.

Abstract: An optical device and a method of manufacturing an optical device. The optical device includes: a conversion means for converting propagation light propagating through an optical waveguide into parallel light and for outputting the parallel light; and a first lens means for focusing the parallel light outputted from the conversion means on a core of an optical fiber. The method includes: converting propagation light propagating through an optical waveguide into parallel light; outputting the parallel light; and focusing, using a first lens, the parallel light on a core of an optical fiber.

Abstract: In an embodiment, an optical receptacle includes a first lens face that is disposed on a first surface 2a on a photoelectric conversion device 3 side in an optical receptacle main body so that a portion of light of the light of a light-emitting element 7 is incident thereon, a first reflective surface 14 that is disposed on a second surface 2b on the side opposite to the first surface 2a and reflects the light that has been incident on the first lens face 11, and a second reflective surface 16 that is disposed on the first surface 2a continuously with the first lens face 11 so that a remaining portion of light of the light of the light-emitting element 7 is incident thereon and reflects the incident remaining portion of light towards a light-receiving element 8 as monitor light are included.

Abstract: The disclosure generally relates to highly efficient light duct light splitters that are capable of splitting the light propagating within a light duct into two different ducts, with nearly 100 percent efficiency. In particular, the described light splitters are configured in a “Tee” shape with a reflective splitter element.

Abstract: A ferrule 10 includes holding holes 16, a light incidence/emission plane 21 to pass light entering or emitted from optical fibers F2 respectively held at the holding holes 16, lenses 31 disposed on an optical axes between the respective holding holes 16 and the light incidence/emission plane 21, and two or more guide portions. A second optical axis L2 between the light incidence/emission plane 21 and the ferrule 10 on the other side is inclined relative to a Z direction. A positional relation between the guide portions is 180-degree rotationally symmetric around a reference axial line extending in the Z direction. The lenses 31 is disposed disproportionately in a direction opposite to an inclination direction of the second optical axis L2 from a position line-symmetric relative to a straight line crossing with the reference axial line and parallel to an X direction.

Abstract: An clip-together optical signal coupling assembly includes a first connector and a second connector. The first connector includes a first main body and first optical coupling lenses. The second connector includes a plurality of second optical coupling lenses. The first connector includes a cover matched with the first main body, the first main body comprising a first top surface, a first bottom surface and a first outside surface connecting the first top surface and the first bottom surface together. The first top surface defines a first recess, with a first inner side surface defining a first fixing portion. The cover includes a second outside surface with a second fixing portion which functions with the first fixing portion to fix the cover to the first main body.

Abstract: According to one embodiment, an optical communication module includes an optical unit and an optical connector. The optical unit includes an optical semiconductor element and a base. The optical semiconductor element has a first optical axis. The base has a first surface and a mounting portion to mount an optical connector. The first surface is perpendicular to the first optical axis. The base is provided with the optical semiconductor element. The optical connector is mounted at the mounting portion and is capable of rotating around the first optical axis. The optical connector includes a first housing and a light-guiding body. The first housing has a second surface facing the first surface and a second axis crossing the first optical axis at a first angle. The light-guiding body is provided inside the first housing and has an end plane perpendicular to the second axis.

Abstract: There is provided a system and apparatus for the transmission of high power laser energy over great distances without substantial power loss and without the presence of stimulated Raman scattering. There is further provided systems and optical fiber cable configurations and optical fiber structures for the delivering high power laser energy over great distances to a tool or surface to perform an operation or work with the tool or upon the surface.

Abstract: An optical coupler for a vehicle lighting system includes a housing having first and second openings, each opening having an optical axis passing through the opening into the housing, with the optical axes of the openings forming an obtuse angle. The optical coupler has one or more optics carried by the housing and arranged between the openings such that light entering the first opening along its optical axis passes through the one or more optics and exits through the second opening along the other optical axis. The optic(s) may include a first Fresnellian surface adjacent the first opening and a second Fresnellian surface adjacent the second opening such that light passing through the optical coupler from the first opening to the second opening passes through both Fresnellian surfaces and is redirected from the optical axis of the first opening to the optical axis of the second opening.

Abstract: A photoelectric conversion device uses an optical coupler to divide a light beam emitted from a light emitter into two portions according to a predetermined ratio. A first light beam portion is guided to an optical fiber, and a second light beam portion is guided to a light receiver. The light receiver can detect an intensity of the second light beam portion. In this way, a processor can calculate an intensity of the light beam emitted from the light emitter accordingly.

Abstract: Systems and methods are provided for adjusting a laser beam applied to a workpiece in a processing operation. A laser processing system receives the laser beam that is associated with a beam quality property. The laser processing system adjusts the laser beam to change the beam quality property based on a characteristic of the workpiece, a characteristic of the processing operation, or a combination thereof. The adjusted laser beam can also be delivered to the workpiece.

Abstract: A photoelectric conversion device includes a circuit board, a light emitting module, a light receiving module, and an optical coupling lens. Two protrusions apart from each other extend from the circuit board. The light emitting module and the light receiving module are mounted on the circuit board and apart from each other. The optical coupling lens includes an oblique reflection surface and a recess having a bottom surface parallel to the circuit board. Two distanced posts perpendicularly extend from the bottom surface and engage with the centers of the protrusions upon assembly to ensure automatic and alignment of the light emitting module with the first converging lens, and alignment of the light receiving module with the second converging lens.

Abstract: An optical coupling lens includes a first reference portion, a second reference portion and a main portion sandwiched between the first reference portion and the second reference portion. The main portion includes a first surface having at least one first converging lens, a second surface having at least one second converging lenses, and a reflecting surface. The second surface is substantially perpendicular to the first surface forming intersection line. An angle between the reflecting surface and the first surface is about 45 degrees. Each reference portion includes a reference member. The reference member includes a reference point. A connecting line of the reference points of the reference portions is substantially parallel to the intersection line.

Abstract: A light guide for a light-based touch-sensitive surface, including first and second curved panels having substantially similar curvatures, wherein light undergoes a first refraction by the first curved panel as it enters the light guide, and undergoes a second refraction by the second curved panel as it exits the light guide, the second refraction being the inverse of the first refraction, and wherein one of the panels is curved in a horizontal plane parallel to the surface and forms a curved rim for the surface.

Abstract: A thermally assisted magnetic recording head includes core that propagates laser light as propagation light, a near-field light generator that faces a portion of the core and extends to an air bearing surface (ABS), the near-field light generator coupled to the propagation light propagating through the core so as to generate a surface plasmon, propagating the surface plasmon to an end part facing the ABS, and generating near-field light at the end part to irradiate the near-field light to a magnetic recording medium, a main magnetic pole layer provided in the vicinity of the near-field light generator where an end part is positioned on the ABS, a laser diode that generates laser light of wavelength 890 nm to 1,000 nm and enters the laser light into the core, and a photodiode provided on a silicon substrate measures an intensity of the laser light entering from the laser diode to the core.

Abstract: An optical rotary transmitter which ensures the reliable transmission of optical signals in conjunction with a comparatively simple construction comprises two parts spaced apart from one another which are rotatable relative to one another about a common centre axis and the first of which comprises a first circular light coupler (10) and the second of which comprises a second circular light coupler (20). The light entrance and light exit surfaces of the two light couplers face one another. Each of the light couplers (10, 20) consists of collimators (11, 21) combined to form a respective collimator arrangement (16, 26), optical coupling elements (15, 25) being connected to said collimators.

Abstract: Embodiments of the invention include an apparatus including an optical fiber having a distal end configured to emit a beam of energy. The apparatus also includes a tube including a tube channel. The distal end of the optical fiber is disposed in the tube channel. The apparatus further includes a shock absorber disposed on the tube and a cap disposed on the shock absorber.

Abstract: An optical fiber connector for coupling light to or from an input fiber is disclosed. The connector includes a first alignment member that holds an achromatic GRIN lens. The achromatic GRIN lens has a half-pitch axial length L, wherein 0.5 mm?L?5 mm. The optical fiber connector has a field fiber that interfaces with the achromatic GRIN lens. The connector is operable between operating wavelengths of 800 nm and 1600 nm with a coupling loss of less than 0.2 dB.

Abstract: The method disclosed provides communication over short distances at high speed via fiber optics making it practical to replace standard copper conductors with optical fiber. This is a solution to the “last mile” problem in Internet high speed communications.

Abstract: A light guide apparatus includes a light guide layer and an injection layer further including light injection elements and respective light bypass elements disposed optically upstream of the light injection elements. The light injection elements and/or the bypass elements may take the form of air prisms. There is an axial index of refraction variation between the light guide layer and the injection layer. The axial index of refraction variation may be discrete or may be an axial gradient index variation.

Abstract: A lens module includes a front lens unit and a bottom lens unit. The front lens unit includes a number of first lenses having parallel optical axes. The bottom lens unit is detachably connected to the front lens unit. The bottom lens unit includes a number of second lenses having parallel optical axes.

Abstract: Provided is an optical module capable of inhibiting both the displacement of an optical axis caused by thermal changes and property degradation in an optical functional circuit. The optical module includes: a planar lightwave circuit including a waveguide-type optical functional circuit and a waveguide region where only an optical waveguide is formed in contact with a side, wherein an emission end face where output light is emitted from the optical functional circuit, or an entrance end face where input light is entered to the optical functional circuit is formed in contact with the side; a fixing mount employed to hold the planar lightwave circuit only in the portion where the waveguide area is located; and an auxiliary mount employed to hold the planar lightwave circuit in contact with a side that is opposite the side where the emission end face or the entrance end face.

Abstract: A waveguide has an input end near a top of a slider coupled to receive light from an energy source. The waveguide delivers the light at an output end of the waveguide near a bottom of the slider. The apparatus includes light blocking members on respective first and second cross track sides of the waveguide. The light blocking members are configured to block stray light away from a light path. The light blocking members are at a location along a length of the waveguide between the top and the bottom of the slider. Confinement of light within the waveguide is near a maximum at the location.

Abstract: A fiber optic bundle couples light from an image intensifier (I2) to an image sensor. The fiber optic bundle includes multiple cores for directing the light from the I2 to the image sensor, and each core has an output surface shaped into a recessed concave surface for focusing the light toward the image sensor. A bond layer is interposed between the output surface of the core and the image sensor. The bond layer is shaped into multiple micro-lenses, each micro-lens configured to conform to the recessed concave surface of each respective core.

Abstract: A semiconductor optical device includes a stem; a semiconductor optical element mounted on the stem; a resin cap including a cylindrical body portion, a plate portion, and an edge portion; and a lens attached integrally to the plate portion of the cap. The edge portion of the cap is bonded to the stem so that the cap covers the semiconductor optical element. The cylindrical body portion of the cap has at least one first portion and second portions which are spaced apart from each other in the circumferential direction of the cylindrical body portion and which project inwardly relative to the at least one first portion. The stem has projections, and each projection vertically underlies and engages or contacts a surface of a respective one of the second portions of the cap.

Abstract: The present application relates to an internal optical spectroscope comprising: a needle sleeve insertable into and removable from targeted living tissue; a shaft housed by the needle sleeve including at least one v-shaped trough including an aft side and a next-to-aft side; a light source comprising variable light wave lengths of both visible and near infrared light; at least one light transmission fiber comprising a transmitting end; at least one light detector fiber comprising a receptive end; and data processor. The present application also relates to a method of performing an optical biopsy in situ.

Abstract: These teachings disclose a multi-purpose electric window that comprises a printed transparent sheet and a reflective layer laminated onto an electric light-switching device and a power source. The electric light-switching device is made of electrically actuated polymer dispersed liquid crystal or suspended polarized particles laminated between two transparent electrodes. There are surface lens structures at one side or both sides of the transparent sheet. Images are printed unto the surface lens structures. The lens structures are selected from prism, half spherical, half cylindrical, pyramidal, Fresnel structure or a combination of the above. The transparent sheet is laminated on the side with reflective layer or the other side of the electric light-switching device without reflective layer. Light emitting diodes can be placed at the sides or under the transparent sheet.

Abstract: An optical fiber assembly includes a prism, four first collimating portions, four second collimating portions, two third collimating portion, two light emitting elements, two light receiving elements, four optical fibers, and two light intensity detectors. The prism includes an incident surface, a first reflecting surface, a first emergent surface, a second reflecting surface, and a second emergent surface. The first collimating portions are positioned on the incident surface. The second collimating portions are positioned on the first emergent surface. The third collimating portions are positioned on the second emergent surface. Each light emitting element faces one of the first collimating portions for emitting light beams. Each light receiving element faces one of the first collimating portions. Each optical fiber faces one of the second collimating portions. Each light intensity detector faces one of the third collimating portions for detecting light intensity of a corresponding light emitting element.

Abstract: An optical coupling lens includes a main body and two plugs. The main body includes a front surface, a back surface opposite to the front surface, a first optical surface, a second optical surface perpendicular to the first optical surface, a reflecting surface obliquely facing the two optical surfaces, first converging lenses formed on the first optical surface, and second converging lenses formed on the second optical surface. The plugs extend from the front surface and sandwich the first converging portions. Each plug includes a cylindrical body portion having a flat end surface, a bowl-shaped protruding portion extending from the end surface and having a top surface away from the end surface, and a buffering portion formed in the top surface. The diameter of the protruding portion decreases from the end surface to the top surface.

Abstract: A luminaire comprising lamellae holding means, a light source, and a set of lamellae comprising a plurality of (inclined) lamellae. The set of lamellae extends at least partially over a light emission window. The lamellae have a reflective front surface facing towards the light source, said front surface being designed to partially reflect light to the exterior and partially transmit light, for example in that the lamellae are diffusely translucent or have a perforated surface. The set of lamellae is provided with light converging means, for example a Fresnel lens, which optionally are integrated in the lamellae to prevent the luminaire becoming too bulky.

Abstract: An optical coupling lens includes a main portion and two reference portions. The main portion includes a first surface having at least one first converging lens formed thereon, a second surface having at least one second converging lenses formed thereon, and a reflecting surface. The second surface is substantially perpendicular to the first surface. An angle between the reflecting surface and the first surface is about 45 degrees. An optical axis of the first converging lens is substantially perpendicular to the first surface, and an optical axis of the second converging lens is substantially perpendicular to the second surface. Each reference portion includes a reference member. The reference member includes a reference point. A connecting line of the reference points of the reference portions is substantially parallel to the first surface and the second surface, and the connecting line is in a surface substantially coplanar with the reflecting surface.

Abstract: Optical systems and components thereof are disclosed which may be used for efficiently coupling laser energy into an optical conduit while maintaining a homogenous beam output from the optical conduit. Some embodiments are directed more specifically to far field beam homogenization of optical fiber coupled radiation.

Abstract: A light-receiving device 10 includes a plurality of light-receiving units 10A, 10B, and 10C, in which, in the element substrate 11A constituting the light-receiving unit 10A, the rear surface of a second terminal forming area 16Ac, upon which a connection pad PAc is formed, is bonded to the front surface of a cover glass 14B covering a plurality of light-receiving elements 12 constituting the light-receiving unit 10B, and in the element substrate 11C constituting the light-receiving unit 10C, the rear surface of a first terminal forming area 16Cb, upon which a connection pad PCb is formed, is bonded with the front surface of the cover glass 14B of the light-receiving unit 10B. As a result, an increase in manufacturing cost and a decrease in yield are mitigated so that it is possible to provide a light-receiving device upon which light-receiving elements are disposed continuously over a long distance at a high density, as well as an optical touch panel device provided with the same.

Abstract: The present invention relates to the apparatus and method for optical interconnection. The present invention provides an optical interconnection structure comprising: a substrate on which double side perforated multi-hole through a predetermined region is formed; bottom hole which is etched and tapered for optical fiber array is bigger than upper hole which is etched for the optical devices. The present invention provides the optical interconnection structure that can facilitate the optical interconnection between the active optoelectronic devices that transmit/receive the optical signals and the optical fiber array, making it possible to align easily and acutely between the optical devices and optical fiber array.

Abstract: The disclosure generally relates to sets of optical waveguides such as optical fiber ribbons and embedded optical waveguides (132a-d), and optical interconnects useful for connecting multiple optical waveguides such as in optical fiber ribbon cables and printed circuit boards having optoelectronic capabilities. In particular, the disclosure provides an efficient, compact, and reliable optical waveguide connector (100) that incorporates microlenses and re-directing elements (136a-d) which combine the features of optical waveguide alignment, along with redirecting and shaping of the optical beam.

Abstract: A flexible optical impact detection sensor is mounted on an outboard portion of the front bumper for signaling an offset rigid barrier impact event to a forward corner of a motor vehicle and deployment of a small offset rigid barrier airbag mounted on the front rail. The airbag is attached proximate a distal end of a front rail. The flexible optical impact detection sensor, attached to a rear surface of an outboard portion of the front bumper, generates a signal upon a corner impact event, whereby a controller processes the signal generated by the impact detection sensor and electrically actuates an inflator upon a predetermined impact severity. The airbag in the inflated condition acts against the offset rigid barrier to generate a lateral force against the offset rigid barrier to push the motor vehicle away from the barrier and thereby redirect impact energy by lateral movement of the motor vehicle.

Abstract: A product and process for fabricating an optical element from a capillary ferrule includes fusing the optical element onto an optical fiber. The optical element starts with a capillary ferrule that is sculpted on one end to form an optical property such as a flat window, ball lens, angled endface or other sculpted shape. The ferrule is fused onto an optical fiber that has been inserted into the ID of the capillary ferrule. As a result, the ferrule serves as a mechanical aligner for the optical element to fiber fusion process.

Abstract: Embodiments of the present disclosure describe semiconductor substrate techniques and configurations for an optical receiver. In one embodiment, a system includes a semiconductor substrate having one or more optical alignment features formed in a surface of the semiconductor substrate and an optical receiver assembly coupled with the semiconductor substrate, the optical receiver assembly including a photodetector device coupled with the surface of the semiconductor substrate, wherein the one or more optical alignment features facilitate precise optical alignment between a lens assembly and the photodetector device when the lens assembly is coupled with the semiconductor substrate using the one or more optical alignment features. Other embodiments may be described and/or claimed.

Abstract: A display unit for a motor vehicle, having a display area with a back-lit liquid crystal display device bounded by a border area is provided. The display unit includes a light source, and behind the display area a liquid crystal cell, a first polarizer and a second polarizer, the light source being configured to provide back-light illumination to the cell and the polarizers forming a pair of polarizers on opposite sides of the cell such that, in use, the first polarizer polarizes the illumination and the second polarizer either passes or blocks this illumination when the polarization of the illumination is rotated by the cell. A first cover sheet extends over said cell, and a second cover sheet extends over the first cover sheet.

Abstract: A fiber end surface machining device includes a base seat, a pair of electrodes, and a fiber position structure. The fiber position structure includes a resisting unit and a driving member. The resisting unit is movably assembled on the base seat and is located between the pair of electrodes. The driving member is rotatably assembled on the base seat adjacent to the resisting unit. The driving member includes a cam portion resisting the resisting unit. When the cam portion rotates to drive the resisting unit to move towards an optical fiber connector, the resisting unit drives an optical fiber of the optical fiber connector to move relative to an optical fiber ferrule of the optical fiber connector, and a length of the optical fiber protruding out of the optical fiber ferrule is adjusted.

Abstract: The present invention relates to an apparatus for wavelength-division multiplexing and demultiplexing, to an optical communication module, and to an optical device. The apparatus for wavelength-division multiplexing and demultiplexing comprises: a first lens block having a lens array at one side thereof; a second lens block having a lens surface corresponding to the lens array and combined with the other side of the first lens block; a receptacle having an optical fiber ferrule fixed at the center thereof and stacked on the second lens block; and a base combined with one side of the first lens block, wherein the first block is stacked on the base.

Abstract: A CW fiber-laser includes a gain fiber having a reflector proximity-coupled to one end, with the other end left uncoated. A laser resonator is defined by the reflector and the uncoated end of the gain-fiber. Pump-radiation from two fast-axis diode-laser bar stacks is combined and focused into the uncoated end of the gain-fiber for energizing the fiber. Laser radiation resulting from the energizing is delivered from the uncoated end of the gain-fiber and separated from the pump-radiation by a dichroic mirror.

Abstract: The invention relates to a device (10) for transmitting data between two rail vehicles (12, 14). At each rail vehicle (12, 14) one data transmission unit (16 to 22, 80, 90, 92) is arranged, wherein between the data transmission units (16 to 22, 80, 90, 92) a data transmission link for transmitting data is formed. Data transmission via this data transmission link is carried out by means of an optical radio relay system.

Abstract: An optical coupling lens which can reveal its own coefficient of signal attenuation includes a refraction surface, a first total reflection surface, a second total reflection surface, a first aligning member and a second aligning member. The refraction surface, the first total reflection surface and the second total reflection surface are connected end to end in order. The first aligning member and the second aligning member are formed on the refraction surface.