Abstract: A breakout box, breakout box system, and method for management of optical fibers. The breakout box system provides a pass-through system for connecting optical fibers to network rack modules. The external routing of incoming and outgoing cables around the rack is kept neat and orderly, with one large cable serving a plurality of shelves. The breakout of the cable and distribution of the fibers to the individual modules occurs inside the breakout boxes and bridges, which provide protection for the fibers while still allowing easy access for fiber handling by means of the removable lids.

Abstract: In various embodiments, an optical alignment structure may be provided. The optical alignment structure may include a light carrying structure configured to receive an input optical light from an external light source. The optical alignment structure may further include a light redirection mechanism coupled to the light carrying structure. The light redirection mechanism may be configured to receive the input optical light from the light carrying structure. The light redirection mechanism may be further configured to redirect the input optical light back to the light carrying structure, the redirected input optical light configured to be detected by a detector for alignment of the optical alignment structure with the external optical source.

Abstract: A fiber coupling device for coupling of at least one optical fiber is disclosed. The fiber coupling device comprises at least one opto-electronic and/or photonic chip comprising at least one opto-electronic and/or photonic integrated element capable of emitting and/or detecting electromagnetic radiation. The fiber coupling device is configured for coupling the at least one opto-electronic and/or photonic integrated element to at least one fiber end-piece of an optical fiber having a reflection surface and a convex exit and/or entrance surface. The fiber coupling device further comprises a fiber end-piece alignment substrate configured for locally contacting and thereby supporting at least one convex exit and/or entrance surface of at least one fiber end-piece in an aligned position relative to the at least one opto-electronic and/or photonic integrated element.

Abstract: Embodiments herein include an optical system that passively aligns a fiber array connector (FAC) to a waveguide in a photonic chip. An underside of the FAC is etched to include multiple grooves along a common axis or plane. Some of these grooves are used to attach optical cables, or more specifically, the fibers of optical cables to the FAC. To do so, the fibers are placed in the grooves and a lid is disposed on the underside of the fibers to hold the fibers in the grooves. The optical system uses other grooves in the FAC to mate with ridges in the photonic chip in order to mechanically couple the FAC to the photonic chip. By registering respective ridges in the photonic chip with grooves in the FAC, the FAC is passively aligned to the photonic chip along at least one optical axis.

Abstract: The present invention provides a packaging device of single optical multiplexed parallel optical receiver coupling system component, comprising a housing having a transmission function, an adapter component and collimating lens. The upper surface of the housing is provided with a first groove and a second groove, the lower surface of the housing is provided with a third groove. One end of the housing is provided with a through hole which communicates with the first groove. One end of the collimating lens is connected with the adapter component, and the other end of the collimating lens passes through the through hole to the first groove. A first slope and a second slope are respectively provided on the adjacent side wall between the first groove and the second groove. The second slope is provided with a reflective film. The third groove is provided with a lens array having multiple channels.

Abstract: Electro-optical connectors and connector systems are disclosed. In one embodiment, an electro-optical plug includes a tip connector, a ring connector, and a sleeve connector, wherein the tip connector, the ring connector, and the sleeve connector are electrically conductive. The electro-optical plug further includes a gradient-index lens co-axially disposed within at least the tip connector, wherein the tip connector has a tip window that optically exposes a coupling surface of the gradient-index lens, and an optical fiber that is co-axially disposed within at least the sleeve connector. In another embodiment, an electro-optical connector includes a plug body having a planar electrical coupling surface with an array of electrically conductive contacts, and an optical coupling surface having at least one optical window. The electro-optical connector further includes a gradient-index lens disposed within the plug body.

Abstract: An optical module includes a substrate, a light emitting element, a light receiving element, and a block by which some of light emitted from the light emitting element is guided to the light receiving element. The block includes a collimating lens, an optical splitter, condensing lenses, a mirror, and a refraction part. The refraction part includes a surface at which a light beam transmitted by the optical splitter is guided to the condensing lens and a surface at which a light beam transmitted by the optical splitter is deflected from the condensing lens.

Abstract: A reduced diameter composite microcable of low weight that is capable of withstanding a tensile load of at least 300 pounds with less than 0.6% fiber strain, is capable of operation between ?40 C and 70 C with less than 0.1 dB/km attenuation change at 1550 nm, and whose outer diameter is less than 15 mm is provided. The microcable includes at least one buffer tube, at least one electrical power conductor, at least one rigid strength member cabled together into a multi-unit core, wherein a plurality of optical fibers are placed within the at least one buffer tube.

Abstract: A cable adaptor case for sorting a first plurality of cables and adapting a plurality of types of cables comprising a cable tray for holding cables, an adaptor tray for adapting a first plurality of cables to a second plurality of cables, and a lid which is removably attached and hingably attached to the cable tray.

Abstract: A method and an apparatus for performing temperature compensation for a camera. The method includes: obtaining temperature information of a camera lens of the camera using a temperature sensor; obtaining a lens target movement position according to position information of a motor that controls a lens of the camera to move and the temperature information; and controlling, according to the obtained lens target movement position, a corresponding lens to move to a target movement position. According to the method and apparatus provided in this application, an imaging quality change, which is caused by a temperature change, of a camera can be compensated for using a simple and convenient method, and practicability is high.

Abstract: A manufacturing method of an imaging module and an imaging module manufacturing apparatus capable of performing positioning of an imaging element unit and a lens unit with high accuracy are provided. A manufacturing apparatus 200 holds a lens unit 10 and an imaging element unit 20 on a Z axis, and images a measurement chart by an imaging element 27 in a state where a probe 113a comes into contact with each of terminals 14A to 14F electrically connected to an x-direction VCM 16A, a y-direction VCM 16C, and a z-direction VCM 16E of the lens unit 10 and electricity flows to a lens drive unit 16 inside the lens unit 10. A contactor of the probe 113a is configured of a non-magnetic material.

Abstract: An adjustable mounting arrangement to position an object of an optical reflecting telescope relative to a base includes at least two support structures connected to the base and to the object. Each of the at least two support structures has two four-link beams arranged nonparallel to each other and a cradle having two connecting links. Each of the two four-link beams has a first strut and a second strut running nonparallel to each other, where each of the first and second struts have a first end and a second end, respectively, and where each of the first and second struts is mounted with articulation via their respective first end in a corresponding inner joint on the object.

Abstract: The invention discloses a three-piece optical lens for capturing image and a three-piece optical module for capturing image. In order from an object side to an image side, the optical lens along the optical axis comprises a first lens with positive refractive power; a second lens with refractive power; and a third lens with refractive power; and at least one of the image-side surface and object-side surface of each of the three lens elements are aspheric. The optical lens can increase aperture value and improve the imaging quality for use in compact cameras.

Abstract: A five-piece optical lens for capturing image and a five-piece optical module for capturing image, along the optical axis in order from an object side to an image side, include a first lens with positive refractive power having an object-side surface which can be convex; a second lens with refractive power; a third lens with refractive power; a fourth lens with refractive power; and a fifth lens which can have negative refractive power, wherein an image-side surface thereof can be concave, and at least one surface of the fifth lens has an inflection point; both surfaces of each of the five lenses are aspheric. The optical lens can increase aperture value and improve the imaging quality for use in compact cameras.

Abstract: A photographing optical lens assembly includes, in order from an object side to an image side, a first lens element, a second lens element, a third lens element, a fourth lens element, a fifth lens element and a sixth lens element. The first lens element has negative refractive power. The second lens element has negative refractive power. The fourth lens element has positive refractive power. The fifth lens element has positive refractive power. The sixth lens element has negative refractive power. The photographing optical lens assembly has a total of six lens elements, and the photographing optical lens assembly further includes an aperture stop.

Abstract: An optical imaging lens includes first, second, third, fourth, fifth and sixth lens elements arranged in order from the object side to the image side. The first lens element has an image-side surface with a concave part in a vicinity of its periphery, the second lens element has an image-side surface with a concave part in a vicinity of the optical axis, the third lens element has positive refractive power, the fourth lens element has an object-side surface with a convex part in a vicinity of its periphery, the fifth lens element has an object-side surface with a concave part in a vicinity of the optical axis, the sixth lens element has an image-side surface with a concave part in a vicinity of the optical axis. The second lens element has negative refractive power. The sixth lens element has positive refractive power.

Abstract: An optical image capturing system includes, along the optical axis in order from an object side to an image side, a first lens, a second lens, a third lens, a fourth lens, and a fifth lens. At least one lens among the first to the fifth lenses has positive refractive force. The fifth lens can have negative refractive force, wherein both surfaces thereof are aspheric, and at least one surface thereof has an inflection point. The lenses in the optical image capturing system which have refractive power include the first to the fifth lenses. The optical image capturing system can increase aperture value and improve the imaging quality for use in compact cameras.

Abstract: A camera lens is disclosed. The camera lens includes a first lens with positive refractive power; a second lens with negative refractive power; a third lens with negative refractive power; a fourth lens with positive refractive power; a fifth lens with negative refractive power; and a sixth lens with negative refractive power. The camera lens further satisfies specific conditions.

Abstract: The present disclosure relates to the field of optical lens, and discloses an optical camera lens, which includes: an aperture, a first lens having positive refraction power, a second lens having negative refraction power, a third lens having positive refraction power, a fourth lens having negative refraction power and a fifth lens having negative refraction power; the optical camera lens satisfies following relational expressions: 0.4<f1/f<0.55, ?0.8<f2/f<?0.7, 2.0<f3/f<2.3, ?1.9<f4/f<?1.7, ?1.6<f5/f<?1.2, 0.3<f2/f4<0.45. The optical camera lens provided by the present disclosure can meet the design requirements on low TTL and large aperture, which can effectively weaken the background and highlight the focusing object.

Abstract: A photographing system includes, in order from an object side to an image side, a first lens element, a second lens element, a third lens element, a fourth lens element, a fifth lens element, a sixth lens element and a seventh lens element with refractive power. The first lens element with positive refractive power has an object-side surface being convex in paraxial region. The second lens element with refractive power has an image-side surface being concave in paraxial region. The third, fourth and fifth lens elements all have refractive powers. The sixth lens element with refractive power has an image-side surface being concave in paraxial region, wherein the image-side surface has at least one convex shape in off-axis region, and both of two surfaces are aspheric. The seventh lens element with refractive power has an object-side surface being concave in paraxial region, and both of two surfaces are aspheric.

Abstract: Methods and apparatus for implementing a camera having a depth which is less than the maximum length of the outer lens of at least one optical chain of the camera are described. In some embodiments a light redirection device, e.g., a mirror, is used to allow a relatively long optical chain with a relatively large non-circular outer lens. In some embodiments the light redirection device has a depth, e.g., front of camera to back of camera dimension, which is less than the maximum length of the aperture of the outer lens in the aperture's direction of maximum extent. Multiple optical chains with non-circular outer lenses arranged in different directions may and in some embodiments are used to capture images with the captured images being combined to generate a composite image.

Abstract: Certain aspects relate to systems and techniques for submicron alignment in wafer optics. One disclosed method of alignment between wafers to produce an integrated lens stack employs a beam splitter (that is, a 50% transparent mirror) that reflects the alignment mark of the top wafer when the microscope objective is focused on the alignment mark of the bottom wafer. Another disclosed method of alignment between wafers to produce an integrated lens stack implements complementary patterns that can produce a Moiré effect when misaligned in order to aid in visually determining proper alignment between the wafers. In some embodiments, the methods can be combined to increase precision.

Abstract: A lens system, from an object side to an image side in the following order, includes; an object-side lens group that is disposed closest to the object side and having positive refractive power; a focusing lens group that moves during a focusing operation and having negative refractive power; a third lens group; a wobbling lens group that vibrates in an optical axis direction; and an image-side lens group that is disposed closest to the image side.

Abstract: A zoom optical system includes a first lens group, a position of which with respect to an imaging plane is adjustable, and including first and second lenses. The zoom optical system also includes a second lens group of which a position with respect to the imaging plane is adjustable and includes third to fifth lenses. The zoom optical system further includes a third lens group including a sixth lens. An object-side surface of the first lens is convex.

Abstract: A projection optical system is constituted by, in order from the reduction side, a first optical system for forming an image displayed by image display elements as an intermediate image, a first optical path bending means that bends an optical path with a reflective surface, and a second optical system for forming the intermediate image on a magnification side conjugate plane. The second optical system is constituted by, in order from the reduction side, a first lens group having a positive refractive power, a second optical path bending means that bends an optical path with a reflective surface, and a second lens group having a positive refractive power. Conditional Formulae (1) and (2) below are satisfied. 10.0<TL1/|f|<50.0??(1) 4.0<TL21/|f|<30.0??(2).

Abstract: A microscope system and method allow for a desired x?-direction scanning along a specimen to be angularly offset from an x-direction of the XY translation stage, and rotates an image sensor associated with the microscope to place the pixel rows of the image sensor substantially parallel to the desired x?-direction. The angle of offset of the x?-direction relative to the x-direction is determined and the XY translation stage is employed to move the specimen relative to the image sensor to different positions along the desired x?-direction without a substantial shift of the image sensor relative to the specimen in a y?-direction, the y?-direction being orthogonal to the x? direction of the specimen. The movement is based on the angle of offset.

Abstract: An optical transmission system configured to image a selected region of a sample arranged in a first medium in an object plane on or in a sample carrier, which includes plane-parallel plate, from the object plane into an intermediate image plane in a second medium. The plane-parallel plate is located between the optical transmission system and the sample during the imaging. The object plane and the intermediate image plane form an angle between 0° and 90° with an optical axis of the transmission system. The optical transmission system is positioned relative to region of the sample such that the sample is located within the focal length of the lens of the optical transmission system closest to the sample. The intermediate image plane and the object plane are located on the same side of the optical transmission system, and the intermediate image is a virtual image.

Abstract: Provided is a laser scanning microscope including a scanning unit that scans laser light emitted from a light source two-dimensionally across a specimen, a light-detecting unit that detects light coming from the specimen, an information-acquiring unit that acquires information about an observation mode, and a control unit that controls the scanning unit based on the information acquired by the information-acquiring unit. The scanning unit includes a galvanometer scanner and a resonant scanner that are alternately operable. The control unit controls the scanning unit to deactivate the resonant scanner if the information acquired by the information-acquiring unit indicates an observation mode in which the galvanometer scanner is used alone and to maintain the resonant scanner in an active state if the information acquired by the information-acquiring unit indicates an observation mode in which the galvanometer scanner and the resonant scanner are alternately used.

Abstract: A three-dimensional (3D) microscope includes various insertable components that facilitate multiple imaging and measurement capabilities. These capabilities include Nomarski imaging, polarized light imaging, quantitative differential interference contrast (q-DIC) imaging, motorized polarized light imaging, phase-shifting interferometry (PSI), and vertical-scanning interferometry (VSI).

Abstract: A method for operating a scanning microscope and for determining point spread functions, with which sample images are recorded with the scanning microscope. The method includes scanning a sample with at least one illuminating light beam; recording at least one sample image with a detector device during a scan by the illuminating light beam; and comprising the point spread function, with which a sample image is recorded, from the at least one sample image. A detector device having receiving elements is used, where the distance between the receiving elements is smaller than a diffraction disk that generates a sample point on the detector device. Detector signals, generated by means of the receiving elements, are read out for each of the different positions of the illuminating light beam on the sample, as a result of which the scanning of the sample allows the detector signals, which are read out, to generate a plurality of sample images.

Abstract: An arrangement for light sheet microscopy including illumination optics with an illumination objective for illuminating a sample, located in a medium on a sample carrier aligned with respect to a plane reference surface, with a light sheet. The arrangement further includes detection optics with a detection objective. The arrangement also includes a separating layer system with at least one layer separating the medium from the illumination and detection objectives. The separating layer system is aligned with a base surface parallel to the reference surface and contacts the medium by this base surface. At least one detection corrective lens, for reducing those aberrations occurring as a result of light to be detected passing obliquely through interfaces of the separating layer system, is configured as free-form lens and is arranged between the detection objective and the separating layer system. Alternatively, it also forms the front lens of the detection objective.

Abstract: An optical device for microscopic observation 4 comprises: a cold stop 13 having openings 13d, 13e corresponding to a low-magnification microscope optical system 5 and being a stop member arranged in a vacuum vessel 12 to let the light from the sample S pass to the camera 3; a warm stop 10 having an opening 14 corresponding to a high-magnification microscope optical system 5 and being a stop member arranged outside the vacuum vessel 12 to let the light from the sample S pass toward the cold stop 13; and a support member 11 supporting the warm stop 10 so that the warm stop can be inserted to or removed from on the optical axis of the light from the sample S, wherein the warm stop 10 has a reflective surface 15 on the camera 3 side and wherein the opening 14 is smaller than the openings 13d, 13e.

Abstract: An imaging system with an imaging lens system for imaging an object into an image plane is disclosed. The imaging lens system contains an optical component for a higher depth of field, of which the refractive power is alterable and the optical effect remains rotation-symmetrical.

Abstract: An image output device according to the present disclosure includes: an image acquisition unit that acquires an image with a first resolution; a high-resolution image acquisition unit that acquires an image with a second resolution, being an image of higher resolution than the image with the first resolution; an enlargement input unit that accepts input of an enlargement ratio; a determination unit that determines whether or not an evaluation score determined based on the accepted enlargement ratio is higher than a certain value; and a transmission unit that transmits the image with the second resolution if the evaluation score is determined to be higher than the certain value, and does not transmit the image with the second resolution if the evaluation score is determined not to be higher than the certain value.

Abstract: A display device includes a first support plate. A pixel region is formed on the first support plate and a reflective layer is positioned in the pixel region. The reflective layer includes a specular reflector and a diffuse reflector.

Abstract: A micromirror including a first layer having a first main extension plane, and a second layer having a second main extension plane, the first main extension plane and the second main extension plane being situated parallel to one another, the first layer and the second layer being sectionally connected to one another via at least one connection area, at least one spring element being implemented in the first layer, a movably suspended mirror plate being implemented in the second layer, the mirror plate having a mirror surface on a first side parallel to the main extension plane and being connected on an opposing second side via the connection area to an anchor of the spring element, a part of the spring element on the second side of the mirror plate being movably situated in relation to the mirror plate. A two-mirror system having such a micromirror is also provided.

Abstract: Disclosed herein is a circuit for determining failure of a movable MEMS mirror. The circuit includes a mirror position sensor associated with the movable MEMS mirror and that generates an analog output as a function of angular position of the movable MEMS mirror. An analog to digital converter converts the analog output from the mirror position sensor to a digital mirror sense signal. Failure detection circuitry calculates a difference between the digital mirror sense signal at a first instant in time and the digital mirror sense signal at a second instant in time, determines whether the difference exceeds a threshold, and indicates failure of the movable MEMS mirror as a function of the difference failing to exceed the threshold.

Abstract: A mirror driving device is provided. A pair of piezoelectric actuator units are disposed at both sides of a mirror unit so as to sandwich the mirror unit, and each piezoelectric actuator unit is connected with an end portion of the mirror unit through a linking unit. The linking unit has a structure including one or more plate-shaped members whose longitudinal direction is a direction perpendicular to a rotation axis, and functions as a plate-shaped hinge unit in which a plate-shaped member is deformed so as to be deflected in the thickness direction by the drive of the piezoelectric actuator unit. The linking unit is provided with a sensor unit that detects the stress to be generated in the linking unit during the rotational drive of the mirror unit by a resonant vibration.

Abstract: A drive system includes an actuator, a waveform generating unit, a driving amplifier, and a bias amplifier. The actuator includes a drive unit. The waveform generating unit generates a voltage waveform for driving the drive unit. The driving amplifier amplifies the voltage waveform so as to apply a voltage to the drive unit. The bias amplifier applies a bias voltage to the drive unit. The driving amplifier and the bias amplifier are coupled to a shared power supply and the ground. The output voltage of the bias amplifier is higher than the minimum output voltage of the driving amplifier.

Abstract: A MEMS device includes a platform carried by a frame via elastic connection elements configured to enable rotation of the platform about a first axis. A bearing structure supports the frame through first and second elastic suspension arms configured to enable rotation of the frame about a second axis transverse to the first axis. The first and second elastic suspension arms are anchored to the bearing structure through respective anchorage portions arranged offset with respect to the second axis. A stress sensor formed by first and second sensor elements respectively arranged on the first and second suspension arms is positioned in proximity of the anchorage portions, on a same side of the second axis, in a symmetrical position with respect to the first axis.

Abstract: A scanning optical system, includes a mirror unit equipped with a first mirror surface and a second mirror surface each of which inclines to a rotation axis; and a light projecting system which includes at least one light source to emit a light flux toward the first mirror surface. A light flux emitted from the light source is reflected on the first mirror surface of the mirror unit, thereafter, reflected on the second mirror surface, and then, projected so as to scan in a main scanning direction onto an object in accordance with rotation of the mirror unit, and the light flux reflected on the second mirror surface is polarized in a range within an angle of ±30 degrees to a direction perpendicular to the main scanning direction on the object side.

Abstract: A three-dimensional drive device of this invention comprises: a hollow shaft; a first motor rotating the hollow shaft; a first spur gear having a central axis common to a central axis of the hollow shaft, arranged in a center of the hollow shaft; a second motor rotating the first spur gear; a bevel gear meshing with the first spur gear, arranged within the hollow shaft; and a second spur gear meshing with the bevel gear, arranged within the hollow shaft, and having an axis of rotation orthogonal to the central axis of the hollow shaft, the bevel gear and the second spur gear being to turn upon moving in the circumferential direction of the hollow shaft along with rotation of the hollow shaft, and the central axis of the hollow shaft and the axis of rotation of the second spur gear being orthogonal to each other.

Abstract: Methods, systems, and apparatuses are disclosed for the protection of optical components used during laser bond inspection. In one embodiment, an optic surface wetting enhancement is provided on a protective optic to assist in forming a substantially flat film of transparent liquid from transparent liquid applied to a surface of a protective optic. A flat film of transparent liquid on a surface of a protective optic may be used to retain debris and effluent backscatter produced during a laser bond inspection process.

Abstract: According to one embodiment, a display device, includes a retroreflective element includes a base, and first and second retroreflectors each retroreflecting light made incident without transmitting the base, and a retarder element disposed between a display module and a polarizing element and between the retroreflective element and the polarizing element, the first and second retroreflectors being adjacent to each other, each of the first and second retroreflectors includes a recess portion on a side facing the retarder element.

Abstract: A head up display apparatus includes: a first mirror having power; a second mirror having power; and a light shielding member provided with an aperture. The aperture is provided between an image display surface and the second mirror. Display light which is output from the image display surface is reflected by the first mirror, the second mirror, and the first mirror in this order, and reaches a front windshield (image reflection surface) by passing through the aperture.

Abstract: During a communication technique, a head-mounted electronic device receives a user command to capture sensory information, where the sensory information is associated with an object in an environment of the head-mounted electronic device, and where the object is associated with a second user of a second head-mounted electronic device. Then, a sensor in the head-mounted electronic device captures the sensory information associated with the object based on the received user command. Moreover, the head-mounted electronic device provides the captured sensory information to a pairing electronic device. Next, the head-mounted electronic device receives connection information from the pairing electronic device if the sensory information specifies the second user. Furthermore, the head-mounted electronic device establishes a secure connection with the second head-mounted electronic device based on the connection information.

Abstract: An illumination module can comprise a circuit board, a semiconductor-based light source mounted to the circuit board, an encasing mounted to the circuit board, and one or more optical surfaces at least partially contained within the encasing. The semiconductor-based light source can emit light in a first illumination pattern. The one or more optical surfaces can be collectively configured to receive the light from the edge-emitting semiconductor-based light source. The one or more optical surfaces can include a single optical surface configured to receive, condition, and redirect the light from the edge-emitting semiconductor-based light source. As such, the one or more optical surfaces can be collectively configured to output the conditioned and redirected light from the illumination module in a second illumination pattern different from the first illumination pattern.

Abstract: There is provided an optical system, including a light-transmitting substrate having at least two major surfaces parallel to each other edges, and an optical device for coupling light into the substrate by total internal reflection. The device includes a polarization sensitive reflecting surface.

Abstract: Disclosed is a light guiding valve apparatus comprising an optical valve, a two dimensional light source array and a focusing optic for providing large area collimated illumination from localized light sources. A stepped waveguide may be a stepped structure, in which the steps may be extraction features optically hidden to guided light, propagating in a first forward direction. Returning light propagating in a second backward direction may be refracted, diffracted, or reflected by the features to provide discrete illumination beams exiting from the top surface of the waveguide. A two dimensional array of viewing windows may be produced. Such controlled illumination may provide for efficient, multi-user autostereoscopic displays with wide viewing freedom and low cross talk and near-eye displays that are substantially transparent.

Abstract: The present invention comprises a compact optical see-through head-mounted display capable of combining, a see-through image path with a virtual image path such that the opaqueness of the see-through image path can be modulated and the virtual image occludes parts of the see-through image and vice versa.