Abstract: Assemblies, optical connectors, and methods for forming fiber arrays using laser bonded optical fibers are disclosed. In one embodiment, a method of forming a fiber array includes placing an optical fiber on a surface of a substrate, directing a laser beam into the optical fiber disposed on the surface of the substrate, melting, using the laser beam, a material of the substrate to create a first laser bond zone between the optical fiber and the surface of the substrate, applying an adhesive to the optical fiber and the substrate to create an adhesive bond zone between the optical fiber and the surface of the substrate, and cutting the optical fiber and the substrate to create a first section of the fiber array and a second section of the fiber array.

Abstract: The present disclosure relates to a fiber optic connection system that uses a slide clip to provide robust retention of a fiber optic connector within a mating fiber optic adapter. In certain examples, the fiber optic connector may be a hybrid connector that provides both electrical and optical connectivity.

Abstract: An optical fiber connector according to the present disclosure includes a hollow housing, a ferrule holder, a spring, a back post and a sealing ring. The hollow housing has four side walls, wherein two of the four side walls are respectively provided with an opening. An annular bevel is formed in the interior of the housing. The ferrule holder is disposed within the housing. The spring is disposed within the housing to push the ferrule holder. The back post is partially disposed in the housing for abutting on the spring. Two protrusions are formed on the back post and respectively fall in the two openings on the housing. The sealing ring is put on the back post, wherein the back post is configured to push the sealing ring toward the annular bevel inside the housing such that the sealing ring abuts on the annular bevel.

Abstract: An optical connector attached to a plurality of buffered optical fibers each including: a bare optical fiber; and a tube in which the bare optical fiber is inserted in. A multi-fiber optical connector is connected to first ends of the buffered optical fibers, and a plurality of single-fiber optical connectors are respectively connected to second ends of the buffered optical fibers. The multi-fiber optical connector includes: a ferrule fixed to ends of the bare optical fibers; a connector housing that houses the ferrule therein; and a tube fixing portion that fixes the tubes to the connector housing. The buffered optical fiber has a bare fiber fixing portion in which the bare optical fiber and the tube are fixed at a location closer to the ferrule than the tube fixing portion within the multi-fiber optical connector.

Abstract: A fiber optic connector assembly, including a boot portion connected to a fiber optic cable, a fixed body portion connected to the boot portion, a rotatable coupler connected to the fixed body portion and configured to rotate about the fixed body portion, a ferrule connected to the rotatable coupler and configured to rotate with the rotatable coupler about the fixed body portion, and a bulkhead adapter configured to receive the rotatable coupler after the rotatable coupler has been turned in one direction and released in another direction.

Abstract: The present disclosure provides an optical fiber receptacle, an optical fiber connection device and an optical fiber receptacle module. The optical fiber receptacle comprises a housing, a plurality of positioning hooks and at least one clamping unit. The housing has a rear wall, and at least one slot opened on an opposite side of the rear wall. The rear wall has an inner surface facing the slot and an outer surface opposite to the inner surface, the slot is used to be inserted by an optical fiber plug. The positioning hook protrudes from the outer surface of the rear wall in a column shape, is used to pass through a mounting hole of a panel to latched with a hole edge defining the mounting hole of the panel.

Abstract: An optical coupling apparatus and method are described. An embodiment of an optical coupling apparatus may include a first optical chip, a second optical chip, and an optical writing waveguide block. In the apparatus, the first optical chip is coupled to the optical writing waveguide block in a first coupling manner, and the second optical chip is coupled to the optical writing waveguide block in a second coupling manner. Furthermore, in the apparatus, the first optical chip is optically interconnected to the second optical chip by using the optical writing waveguide block. Compatibility between a plurality of coupling manners is therefore enabled by using the technical solutions described herein.

Abstract: A semiconductor chip provides an optical medium for light propagation. The semiconductor chip includes a chip surface with an outer perimeter and a cavity in the chip surface. The cavity includes a peripheral wall and a bottom surface surrounded by the peripheral wall, the bottom surface adiabatically couplable to an optical waveguide. The cavity is located at an area of the chip surface spaced from the outer perimeter thereof.

Abstract: A fiber optic termination sealingly connects to a cable which includes a casing having a cable tube and optical fibers. The termination includes a sealed housing, a manifold, a connector and termination tubes. The housing has an inlet to sealably receive the cable. The fibers extend from an end of the cable into a sealed chamber of the housing. The manifold is positionable in the housing, and has an inlet to receive the fibers and sealed passages shaped to distribute the fibers therethrough the connector includes contacts communicatively connectable to equipment and the fibers. The termination tubes are positionable within the chamber of housing, and have an entry end sealingly connectable to an end of the cable tube and a contact end sealingly connectable to the contacts.

Abstract: A wall box includes an enclosure having a base and a cover connected to the base. The base and the cover enclose an interior region. The wall box further includes a plurality of fiber optic adapters mounted to the enclosure. The fiber optic adapters include an inner port positioned inside the interior region and an outer port positioned at an outer surface of the enclosure. A tray stack is mounted within the interior region. The tray stack includes a tray mount pivotally connected to the enclosure. The tray mount includes a top surface and an oppositely disposed bottom surface. A first splice tray mounting area is disposed on the top surface and a second splice tray mounting area is disposed on the bottom surface. A plurality of trays is disposed in the first splice tray mounting area. A tray is disposed in the second splice tray mounting area.

Abstract: High-connection density and bandwidth fiber optic apparatuses and related equipment and methods are disclosed. In certain embodiments, fiber optic apparatuses are provided and comprise a chassis defining one or more U space fiber optic equipment units. At least one of the one or more U space fiber optic equipment units may be configured to support particular fiber optic connection densities and bandwidths in a given 1-U space. The fiber optic connection densities and bandwidths may be supported by one or more fiber optic components, including but not limited to fiber optic adapters and fiber optic connectors, including but not limited to simplex, duplex, and other multi-fiber fiber optic components. The fiber optic components may also be disposed in fiber optic modules, fiber optic patch panels, or other types of fiber optic equipment.

Abstract: Drop cable assemblies that can be routed from an outdoor terminal directly to an indoor wall outlet without disruption, and adhered to the interior of a dwelling after removal of the drop cable jacket and utilization of a pre-applied adhesive layer are described. Additionally, telecommunications systems utilizing such assemblies, methods of routing such assemblies and methods of making such assemblies are described.

Abstract: A process and system for making a water resistant cable component and water resistant cable components are provided. The water resistant cable includes a cable body including an inner surface defining a channel within the cable body and an elongate cable component located within the channel of the cable body. The cable also includes a contiguous layer of crosslinked super absorbent polymer surrounding the elongate cable component. The layer of crosslinked super absorbent polymer is formed by applying a liquid layer including a carrier material and an uncrosslinked super absorbent polymer pre-polymer material onto an outer surface of a component of the cable and then by crosslinking the super absorbent polymer pre-polymer while on the cable component to form a layer of crosslinked super absorbent polymer surrounding the cable component.

Abstract: A camera module comprises a lens barrel, a lens driving device including a focusing unit moving a lens barrel in an optical axis direction and a movement correction unit moving the lens barrel in a direction perpendicular to the optical axis direction, and a housing accommodating the lens barrel and the lens driving device. A focus sensing portion of the focusing unit is disposed in an area not including a planar surface on which a focusing magnet and a focusing coil are mounted.

Abstract: A lens module including a base, a lens, a front cover, a first shielding plate set, a second shielding plate set, and a gasket is provided. The lens is disposed on the base. The front cover is rotatably disposed above the base and the lens, and the front cover has a first through hole. Each of the first shielding plate set and the second shielding plate set is pivoted on the base. The second shielding plate set and the first shielding plate set interfere with each other. The gasket is fixed in the first through hole and coupled to the second shielding plate set. The gasket has a second through hole. When the base and the front cover rotate relative to each other, the gasket rotates with the front cover and drives the first shielding plate set and the second shielding plate set to limitedly swing.

Abstract: An optical system includes, from an image side to an object side, a first lens having a positive refractive power, a second lens having a positive refractive power, and a third lens having a negative refractive power. The first lens, the second lens, and the third lens form an optical path with the object side facing a screen and the image side adapted to provide an image from the screen to a user. In one aspect, the optical system is adapted to correct at least one of a group of aberrations including astigmatism and field curvature; or, lateral color.

Abstract: A reconnaissance objective lens used for an unmanned aircraft, the reconnaissance objective lens comprising a first lens (L1), a second lens (L2), a third lens (L3), a fourth lens (L4) and a fifth lens (L5) successively and coaxially arranged along the transmission direction of incident light rays. The first lens (L1) is a biconvex lens, the second lens (L2) is a biconcave lens, the third lens (L3) is a meniscus lens, the fourth lens (L4) is a meniscus lens, and the fifth lens (L5) is a meniscus lens. The first lens (L1) and the second lens (L2) are glued to one another, and the fourth lens (L4) and the fifth lens (L5) are glued to one another.

Abstract: A camera lens is disclosed. The camera lens includes, in an order from an object side to an image side, a first lens with a positive refractive power, a second lens with a negative refractive power, and a third lens with a positive refractive power. The camera lens further satisfies specific conditions.

Abstract: This disclosure discloses an optical imaging lens assembly, sequentially arranged from an object side to an image side along an optical axis, comprising: the first lens element with positive refractive power, the second lens element with negative refractive power having a convex object-side surface and a concave image-side surface, the third lens element with positive refractive power, the fourth lens element with negative refractive power having a concave object-side surface and a convex image-side surface, the fifth lens element with refractive power having a concave image-side surface, and both object-side surface and image-side surface being aspheric, wherein a stop and an image sensor disposed on an image plane are also provided. By such arrangements, the image pickup optical system satisfies conditions related to shorten the total length and to reduce the sensitivity for use in compact cameras and mobile phones with camera functionalities.

Abstract: The present disclosure discloses a camera optical lens. The camera optical lens including, in an order from an object side to an image side, a first lens, a second lens, a third lens, a fourth lens, a fifth lens, a sixth lens and a seventh lens. The camera optical lens further satisfies specific conditions.

Abstract: There is provided a lens system includes a first optical system and forms an intermediate image, which has been formed inside the first optical system by light from an input side, into a final image. The first optical system includes a first subsystem, with the first subsystem including a first lens that is disposed at a position closest to the intermediate image on the input side and moves during focusing and a second lens that is disposed at a position closest to the intermediate image on the output side and moves during focusing.

Abstract: A super-wide angle lens and a photographing apparatus including the super-wide angle lens are provided. The super-wide angle lens includes a first lens having a negative refractive power and a second lens having a positive refractive power, wherein the first lens and the second lens are disposed in sequential order from an object side to an image side, and wherein the super-wide angle lens has a half view angle of 80 degrees or greater.

Abstract: The invention relates to a light microscope for examining microscopic objects with high throughput. The microscope comprises a light source for illuminating a measuring zone, a sample vessel, in which the microscopic objects can be successively moved into the measuring zone, and a detection device for measuring detection light, which originates from a microscopic object located in the measuring zone. According to the invention, the microscope is characterized in that the imaging means comprise a detection lens having a stationary front optics and movable focusing optics, wherein the focusing optics is arranged behind the front optics and in front of an intermediate image plane, and can be adjusted for the height adjustment of a detection plane. The invention further relates to a corresponding microscopy method.

Abstract: A method for flexible inspection of a sample includes forming an input beam using a beam source, blocking a portion of the input beam using an input mask, and forming a shaped beam from a portion of the input beam. The shaped beam is received at a first portion of an objective lens and focused onto a sample. A reflected beam is collected at a second portion of the objective lens. Scattered light is collected at the first and second portions of the objective lens and at a third portion of the objective lens. The scattered light is received at a dark-field detector module and a portion of the scattered light is directed to a dark-field detector. The dark-field detector module includes an output mask having one or more output apertures that allow at least part of the scattered light that passes through the third portion of the object lens to pass as the portion of the scattered light that is directed to the dark-field detector.

Abstract: An optical zoom device for setting an imaging scale of an imaging device, which is configured for imaging an object on an image plane of an image recording device using a microscope objective, comprising an optical element arrangement is disclosed. The optical element arrangement includes an object-side zoom entrance for optical connection to an objective exit, in particular a collimated objective exit, of the microscope objective and includes an image-side zoom exit for optical connection to an image recording entrance of the image recording device.

Abstract: An emitting section of a light projecting section is provided to surround an optical axis of an objective lens of a lens unit. The optical axis of the emitting section is substantially the same as the optical axis of the objective lens. Ring illumination is irradiated on the observation target from the emitting section and light from the observation target is received by an imaging section via the objective lens, whereby first original image data is generated. Directional illumination is irradiated on the observation target from the emitting section and the light from the observation target is received by the imaging section via the objective lens, whereby second original image data is generated. Image data for display indicating an image of the observation target that should be obtained when it is assumed that light in a specific emitting direction is irradiated on the observation target is generated.

Abstract: In an image acquisition device, imaging is performed using an imaging element capable of rolling reading an optical image of a sample irradiated with instantaneous light. Therefore, the image can be captured with a sufficient S/N ratio even when the optical image is weak. Further, the image acquisition device includes a light source control unit that causes the instantaneous light to be emitted from a light source from the start of exposure of a pixel row of which reading last starts to the start of reading of a pixel row of which the reading first starts. That is, in the image acquisition device, the light source control unit causes the sample to be irradiated with the instantaneous light from the light emitting means during a period of time in which all pixel rows of the imaging element are exposed.

Abstract: An objective optical system of an observation unit of the endoscope has a zoom function, and the movable lens for changing a zoom magnification of the objective optical system is controlled to be capable of moving to only a plurality of step positions SP1 to SP4 where specific zoom magnifications are obtained. A control circuit, which controls the movable lens, considers the number N of repetitions and the duration of an on-operation of a zoom switch that instructs the movable lens to move. For example, the movable lens is moved by a step corresponding to the number N of repetitions of the on-operation, and is moved to a step position, which is provided at an end, in a case in which the duration of the on-operation is long.

Abstract: A near-eye-display device includes a pair of fluid-filled lenses. The power of an inner lens of the pair of lenses can be set to position a focal plane for a virtual object from infinity to a predefined distance. The optical power of an outer lens of the pair of lenses is set to cancel out the optical power of the inner lens. A single actuator coupled to a reservoir pumps fluid into or out of the lenses to change their optical power. When the actuator is activated, fluid flows into one of the lenses in a pair and out of the other lens in the pair. The amount of fluid in each lens in a pair of lenses is thereby maintained to cancel out the optical power of the other lens. A single actuator can also be utilized to modify the power of two or more pairs of lenses.

Abstract: An optical scanning device including: a first mirror having a first reflecting surface; a second mirror having a second reflecting surface; two non-waveguide regions disposed between the first and second mirrors and that are spaced apart from each other in a first direction parallel to at least either the first reflecting surface or the second reflecting surface; and an optical waveguide region disposed between the first and second mirrors and that is sandwiched between the two non-waveguide regions. The optical waveguide region propagates light in a second direction that crosses the first direction. The optical waveguide region and the two non-waveguide regions include respective first regions in which a common material exists. The optical waveguide region or each of the two non-waveguide regions further includes a second region in which a first material having a refractive index different from the refractive index of the common material exists.

Abstract: Described herein are embodiments of fiber scanning systems and methods of scanning optical fibers. The disclosed systems and methods advantageously provide an improvement to the scanning range, the oscillation amplitude, and/or the maximum pointing angle for an optical fiber in a fiber scanning system by inducing a buckling of a portion of the optical fiber.

Abstract: A compact camera lens washing device received in a shroud for mounting to a vehicle. The device includes a washer housing disposed in the shroud. The washer housing includes a ring portion and a fluid source attachment. The ring portion has a main opening that is generally aligned with a lens opening of the shroud for receiving the camera lens, an attachment side that is configured to mount the washer housing to the shroud, and a washing side that is configured to frame the camera lens. The washing side is in fluid communication with the fluid source attachment. Nozzles are disposed in a transition portion of the washer housing between the ring portion and the fluid source attachment of the washer housing. The nozzles are configured to discharge fluid from the washer side and radially inwardly towards the main opening that receives the camera lens.

Abstract: An image display device includes a transparent plate which may be disposed in an inclined manner with respect to a display section of a portable terminal provided with the display section. A display displayed on the display section may be reflected on the transparent plate. A space behind the transparent plate may be viewed through the transparent plate and, at the same time, an image on the display section of the portable terminal may also be viewed while being reflected on the transparent plate.

Abstract: A method and apparatus for self-relative body tracking in virtual reality systems using magnetic tracking is disclosed, which allows more accurate tracking of a user's body relative to the user's field of vision. A head-mounted magnetic tracking (HMMT) system is used, in which other parts of a user's body are tracked relative to the HMD on the user's head, rather than relative to a base station. This results in less distortion of the magnetic field used for tracking and thus allows for more accurate determination of the position and orientation of a user's body parts relative to the user's field of vision, so that a more accurate avatar may be presented on the HMD to the user. This allows the avatar of the user's body part to be shown in a location that corresponds closely to its physical position. In an alternative embodiment, multiple portions of the user's body may be tracked.

Abstract: Aspects of the present invention relate to methods and systems for the see-through computer display systems. In embodiments, the systems and methods use curved display panels to generate image light.

Abstract: Disclosed is an electronic device. The electronic device comprises: a display for displaying virtual reality (VR) content; a detection unit for detecting a distance between the electronic device and at least one from among a user and a terminal device held by the user; and a processor for determining a virtual field of view corresponding to the distance detected by the detection unit, and controlling the display to display a screen including a VR content area corresponding to the virtual field of view.

Abstract: A HMD device includes an illumination system, a display device, a lens module and a waveguide system. The illumination system includes an aperture stop. The display device converts an illumination beam into an image beam. The waveguide system guides the image beam, and projects the image beam to a projection target. The waveguide system includes a first waveguide element and a second waveguide element. The image beam is projected to the projection target through the lens module, the first and the second waveguide elements, and is converged to a first stop within the first waveguide element. The first stop is located in the first waveguide element. The image beam is projected to a second stop outside the second waveguide element. The second stop is located at the projection target. The illumination beam is converged to a third stop within the illumination system. The aperture stop is located at the third stop.

Abstract: The laser transformer lens is a hollow shaped translucent lens that transforms a laser beam into a laser sheet substantially which is capable of spanning a planar space nearly. In the event that the optical characteristics of the laser beam and the laser transformer lens are designed properly, a laser sheet of controlled form may be developed as the laser light enters, traverses, and exits the lens. The projection of the transmitted laser sheet, as it impinges on an opaque surface remote from the laser transformer lens results in a laser curve along the surface area which the laser sheet strikes. Moreover, hybrid designs of the laser transformer lens may tune substantially the waveform characteristics such as: wave speed, phase velocity, group velocity, reflection, transmission, refraction, amplitude modulation, frequency modulation, attenuation, fan angle, and wave width.

Abstract: A freeform surface off-axial three-mirror image-side telecentric optical system comprises a primary mirror, a secondary mirror, a tertiary mirror and an image sensor. The secondary mirror is the aperture stop. A reflective surface of the primary mirror is a fourth-order polynomial freeform surface of xy. Each of a reflective surface of the secondary mirror and a reflective surface of the tertiary mirror is a sixth-order polynomial freeform surface of xy.

Abstract: Aspects of the disclosed apparatuses, methods and systems provide coating profiles for optics of a stereoscopic vision system configured to reduce unwanted light. Offset masks are used to provide gradient coating thicknesses. A method of forming the optical system with coatings and mechanical holder used during the method also are provided.

Abstract: Color separation devices, and image sensors including the color separation devices and color filters, include at least two transparent bars that face each other with a gap therebetween. Mutually-facing surfaces of the at least two transparent bars are separated from each other by the gap such that the at least two transparent bars allow diffraction of visible light passing therebetween. The at least two transparent bars have a refractive index greater than a refractive index of a surrounding medium.

Abstract: The cost and power consumption of an imaging apparatus are reduced by facilitating detection of an incident angle of a light beam transmitted through a grating substrate. An image sensor converts an optical image captured by pixels arranged on an imaging surface and outputs the converted image signal. A modulator is configured to modulate intensity of light; and an image processing circuit performs image processing of the output image signal. The modulator has a grating substrate, a grating pattern formed on a back surface side of the grating substrate arranged in proximity to the light receiving surface of the image sensor; and a grating pattern formed on a front surface facing the back surface. Each of the grating patterns is constituted of concentric circles. The modulator performs intensity modulation on the light transmitted through the grating pattern and outputs the modulated light to the image sensor.

Abstract: A photographing optical device may include a movable module including a movable body and a holding body; a support body to hold the movable module; a lens drive coil attached to the movable body; a shake correction coil attached to the support body, and a plurality of drive magnets attached to the holding body. The holding body may include a first magnet fixing member and a second magnet fixing member. The first magnet fixing member and the second magnet fixing member may be formed in a frame shape. The movable body may be disposed on inner peripheral sides of the first magnet fixing member and the second magnet fixing member. The support body may include a case body structuring an outer peripheral face of the support body. An object side end of the case body may include a facing part which faces an end face of the movable body.

Abstract: Provided is a telescope (TSC) having: an objective optical system (OB); an erecting optical system (PR) for erecting an image formed by the Objective optical system (OB); and an eyepiece optical system (EP) for observing the image which is formed by the Objective optical system (OB) and erected by the erecting optical system (PR). The objective optical system (OB) includes, in order from an object, a first lens group (G1) having positive or negative refractive power, a second lens group (G2) having positive refractive power, and a third lens group (G3) having negative refractive power. The second lens group (G2) and the third lens group (G3) rotate together around a point (O) on the optical axis of the Objective optical system (OB) in order to correct the image.

Abstract: An electromagnetic driving device is provided which includes a stationary portion, an OIS driving assembly, a movable portion, and a flexible member. The stationary portion and the movable portion are arranged along a main axis. The OIS driving assembly is configured to drive the movement of the movable portion relative to the stationary portion. The flexible member extends on a plane that is located on a side of the moveable portion and connects the movable portion to the stationary portion.

Abstract: According to one aspect of the present invention, there is provided an imaging lens including: an image shake correcting action unit provided movably in a direction perpendicular to an optical axis of the lens; a stationary unit for supporting the image shake correcting action unit; a permanent magnet provided on one of the image shake correcting action unit and the stationary unit and a coil provided on an other; a drive circuit for moving the image shake correcting action unit relative to the stationary unit; a mount section for being connected to an imaging unit; and a conductive member which is nonmagnetically conductive and disposed between the coil and the mount section so as to include a facing surface facing a surface formed by a winding wire of the coil and having a larger area than a surface formed by an inner periphery of the coil.

Abstract: Implementations of a counterweight device for eyeglasses are provided. In some implementations, a counterweight device may be secured to the backend of each temple and thereby remove some to all weight of the eyeglasses from the nose and/or cheeks of the wearer. In some implementations, a pair of counterweight devices may be used to counterbalance the weight of a pair of eyeglasses. In some implementations, a counterweight device may comprise an elastic loop attached to a weight by a connector. In some implementations, a counterweight device may include fasteners configured to removably secure a weight to an elastic loop or to another weight dangling from an elastic loop. In this way, through the use of threaded fasteners, the overall weight and/or look of a counterweight device may be changed by the wearer. In some implementations, a lanyard may be used in conjunction with a pair of counterweight devices.

Abstract: The present description provides an eyewear lens attachment assembly that provides easy and secure attachment between a lens in a frame. An exemplary eyewear lens attachment assembly described herein includes a lens having a lens opening proximate a nose region, a frame holder having a frame engagement feature and a retainer engagement feature, and a slidable retainer including an outer surface, an inner surface, and a flanged projection extending outwardly from the inner surface. When the flanged projection is positioned through the lens opening, the retainer is slidable between an engaged position in which the retainer is secured to the frame holder and a disengaged position in which the retainer and frame holder may be separated.

Abstract: Glasses having a frame and two lenses. Each of the lenses is attached to the frame. A distance measurement module determines a distance to an object viewed from the glasses. The glasses also include a motion control module for raising and lowering the first and second lens and a controller for determining when it is appropriate to raise the first and second lenses. When the controller determines that it is appropriate to raise the first and second lenses to a raised position, the controller directs the motion control module to raise the first and second lenses. In one embodiment, each lens has a plurality of lens sections which may provide different types of focus. The lenses may be raised or lowered appropriately to allow view through one of the lens sections.

Abstract: An ophthalmic device having posterior and anterior features are disclosed herein. An example ophthalmic device may include an enclosure having an insert disposed therein. The enclosure may include a cornea contact disposed on a posterior side and arranged to rest on a user's cornea outside of a central cornea area when the ophthalmic device is worn by a user. The enclosure further includes a channel formed in the posterior side, where the channel extends through the cornea contact from at least radially outside of the insert to an inner edge of the cornea contact, and a fenestration formed there through, wherein the fenestration is arranged radially outside of the insert and formed to intersect with a proximate end of the channel.