Abstract: A photonic device comprising a first waveguide core and a second waveguide core. The first waveguide core is asymmetric relative to an imaginary plane that bisects a height of the first waveguide core and is parallel to the bottom surface of the first waveguide core throughout a first region of the photonic device. A side surface of the second waveguide core is parallel to the first waveguide core throughout the first region of the photonic device.

Abstract: Localized strain is effectively eliminated in a shape sensing optical fiber where the fiber exits a link in a kinematic chain. In one aspect, the fiber is positioned in a channel within a fiber fixture portion of the link, and a surface of a lip of the channel is curved. The curved surface of the lip begins tangent to a wall of the channel and has a maximum radius of curvature that is less than the minimum bend radius that the fiber will experience during shape sensing. In another aspect, the fiber is positioned within a shape memory alloy tube that extends from the link.

Abstract: The invention provides an optical connector for coupling with a complementary optical connector and for supporting an optical component. The connector comprises a cover moveable between a first and second position. The cover may also comprise a moveable shield and biasing components. There is also provided an optical connector assembly comprising covers that sequentially open. A PCB comprising waveguides and an optical component sub-mount for integrating with the PCB is also presented.

Abstract: A coupling for detachable connection of a light guide to a coupling counterpart, includes a coupling body that is connected to a light guide frame, a gripping casing that surrounds the coupling body, and at least one locking hook that is movably held in a radially resilient manner for locking engagement behind at least one locking projection of the coupling counterpart, whereby the gripping casing is rotatably supported on the coupling body and the locking hook can be lifted out of locking engagement by rotary movement of the gripping casing. The locking hook is pre-tensioned and held in a locking position in response to an elastic force of a resilient tongue that carries the locking hook. The coupling body merges into the resilient tongue in an axial direction such that an exterior surface of the coupling body and an exterior surface of the resilient tongue are level with each other.

Abstract: A tool set for terminating an optical fiber with a fiber optic connector includes a crimping tool and a polishing tool. The crimping tool includes a locating feature for locating a housing of the fiber optic connector, a stop for locating an end of an optical fiber relative to the housing, and at least one anvil for crimping a crimp of the fiber optic connector to secure a position of the optical fiber relative to the housing. The polishing tool includes a locating feature for locating the housing and thereby locating the end of the optical fiber and a seat for activating a compression member of the fiber optic connector thereby securing the end of the optical fiber to the polishing tool.

Abstract: An optical transmission module in which optical axis adjustment is possible in a wide range and with a high accuracy, and a method of manufacturing the optical transmission module are provided. An optical transmission module includes a light source that outputs light, a mirror that reflects the light output by the light source, a lever on which the mirror is arranged and that has a fulcrum, a lens that converges the light reflected by the mirror, and a waveguide that transfers the light converged by the lens, with a core having a section width smaller than a wavelength in vacuum of the light.

Abstract: A pluggable optical transceiver module for inserted into plugging slot includes main body and sliding component. The main body has opposite two side surfaces and two sliding slots. The two sliding slots are located at the two side surfaces. The sliding component includes linkage arm and two extending arms. The two extending arms are connected to the linkage arm. Each extending arm has a second fastening part. The main body is between the two extending arms. The two extending arms are disposed on the two sliding slots to have fastening position and releasing position. Two first fastening parts are fastened to the two second fastening parts when the two extending arms are located at fastening position. The two second fastening parts press the two first fastening parts, respectively, for the two first fastening parts being farther from each other when the two extending arms are located at releasing position.

Abstract: An optical-electrical composite connector includes a housing that can accommodate an extra portion of an optical fiber. The optical-electrical composite connector further includes a contact portion for electrically contacting with a mating connector, and a dividing member for dividing the housing into a first space and a second space. The optical fiber is disposed in the first space of the housing divided by the dividing member, and at least a part of the optical fiber is bent. At least another part of the optical fiber, which is other than the part accommodated in the first space thereof, is disposed in the second space of the housing divided by the dividing member.

Abstract: A mechanism for an optical transceiver to latch with and release from a cage is disclosed. The mechanism includes a bail rotatable around an axis and a slider linearly movable between the latching position and the releasing position. The rotation of bail is independent of the liner motion of the slider.

Abstract: Fiber optic cable sub-assemblies having a fiber optic cable including at least one optical fiber attached to a circuit board are disclosed. The circuit board includes an active optical component in operable communication with the optical fiber for forming an active optical cable (AOC) assembly. A strain relief device attaches an end portion of the fiber optic cable to the circuit board, thereby forming the cable sub-assembly. Methods of assembling the fiber optic cable sub-assembly are also disclosed and include the step of attaching an end portion of the fiber optic cable to the circuit board.

Abstract: A parallel optical module includes a light-emitting or light-receiving element array 101 placed on a substrate 100, an optical connector 103 optically connecting the optical element array 101 and an external optical fiber array 105, the optical connector 103 having a shape of at least an octahedron which is bilaterally symmetrical about the center of the outer shape thereof viewed along the optical axis direction, and an engaging member 104 placed on the same substrate 100 as the substrate on which the optical element array 101 is mounted, the engaging member having a groove onto which the optical connector 103 is fitted. A side wall of the groove of the engaging member 104 has an inclination corresponding to, among each surface of the optical connector 103, a second surface 110 adjacent to a first surface 109 facing the optical element array 101 in the direction perpendicular to the substrate.

Abstract: An optical cable module is disclosed. The optical cable module comprises a connector and an optical cable, and the optical cable is connected to the connector. The optical cable comprises at least one optical fiber, an outer cladding layer and a power line, and the outer cladding layer surrounds the at least one optical fiber and the power line, and the power line is configured to supply an electrical power.

Abstract: A cable including an outer metal tube and a first layer wire inside the outer metal tube, wherein the first layer wire has five inner elements surrounding a metallic center member and at least one of the inner elements is a metal tube containing an optical fiber.

Abstract: A fiber optic telecommunications device includes a rack for mounting a plurality of chassis, each chassis including a plurality of trays slidably mounted thereon and arranged in a vertically stacked arrangement.

Abstract: A fiber optic enclosure includes a housing including a base and a cover that cooperatively define an interior region of the housing; and a cable spool assembly rotatably disposed in the interior region of the housing. The cable spool includes a drum portion; and a tray assembly engaged to the drum portion and configured to rotate in unison with the drum portion when the cable spool assembly is rotated relative to the base. The tray assembly includes at least a first tray. Each tray includes optical adapters disposed in a row along a first end of the tray. Certain types of trays are pivotal relative to the drum portion along a pivot axis extending generally parallel to the row of adapters along a second end of the tray opposite the first end. Other types of trays include a second row of optical adapters that pivot relative to the first row.

Abstract: A lens driving device including: a lens holder; a coil mounted on the lens holder; at least one magnet disposed around the coil; a first and second spring members which support the lens holder at the both sides thereof in the optical axis direction so that the lens holder can move freely in the both directions of the optical axis of the lens in an initial state of no electric current to the coil; and an abutment surface to which the lens holder abuts when the lens holder moves toward one spring member against a biasing force of the one spring member; wherein the lens holder is exhorted a biasing force by the other spring member from the side of the other spring member to the side of the one spring member in the optical axis direction when the lens holder abuts against the abutment surface. Thus the lens driving device can support a lens holder in a stable fashion.

Abstract: An image capture device includes: a first and second optical system including a first and second focus lens, respectively; a first image sensor that outputs an electrical signal representing a subject image that has been produced through the first focus lens; a second image sensor that outputs an electrical signal representing a subject image produced through the second focus lens; and a drive controller that moves the first and second focus lenses along their optical axes. The drive controller has the second focus lens follow a position determined by a position of the first focus lens until the first focus lens reaches a position close to in-focus position, and then moves the first and second focus lenses to in-focus positions independently of each other once the first focus lens has reached the position close to the in-focus position.

Abstract: A lens module includes a driving device, an image sensing device, a lens group frame, and an infrared filter. The driving device has a lens barrel for an optical signal passing through. The image sensing device is on a path of the optical signal to convert the optical signal into an electric signal. The lens group frame is provided in the lens barrel, and has a main body, which is driven by the driving device to be moved between a first position and a second position, and a lens holder, which is pivotally connected on the main body and is swung between a third position and a fourth position when the main body is respectively at the first and the second positions. The infrared filter is provided on the lens holder, and is precisely aligned with the image sensing device when the lens holder is at the fourth position.

Abstract: A wide-angle lens is applicable to a head-mounted display having a display screen. The wide-angle lens includes a first lens having a positive refractive power and a second lens having a positive refractive power. Light emitted by the display screen passes to a user through the second lens and the first lens sequentially. The wide-angle lens satisfies the following conditions: - 0.65 < f f 1 - f f 2 < 0.60 ? ? and ? ? 0.2 < f 1 f 2 < 3.8 , where f1 and f2 are the focal lengths of the first lens and the second lens, respectively, and f is the focal length of the wide-angle lens. The wide-angle lens has a greater view angle and achieves better parallax correction.

Abstract: Disclosed herein is an imaging lens unit, including: a first lens having a positive (+) power; a second lens having a negative (?) power; a third lens selectively having one of a positive (+) and negative (?) power; a fourth lens having a negative (?) power; and a fifth lens having a negative (?) power, wherein the first lens, the second lens, the third lens, the fourth lens, and fifth lens are arranged in order from an object to be formed as an image, and the fourth lens is concave toward an image side.

Abstract: A lens assembly includes a first lens, a second lens, a stop, a third lens and a fourth lens, all of which are arranged in sequence from an object side to an image side along an optical axis. The first lens and the fourth lens are with negative refractive power. The second lens and the third lens are biconvex lenses with positive refractive power. The first, third, fourth lens include an object side surface and an image side surface respectively, wherein at least one of the object side surface and the image side surface is an aspheric surface. The lens assembly satisfies: 0<|f1/f2|<|f4/f3|<2, f/D12>1 wherein f1, f2, f3, f4, and f is an effective focal length of the first, second, third, fourth lens and the lens assembly, and D12 is an interval from the first lens to the second lens along the optical axis.

Abstract: A photographing optical lens 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, a seventh lens element and an eighth lens element. The second lens element has positive refractive power. The eighth lens element has an image-side surface being concave in a paraxial region thereof, wherein the image-side surface of the eighth lens element has at least one convex shape in an off-axis region thereof, and both an object-side surface and the image-side surface thereof are aspheric. The photographing optical lens system has a total of eight lens elements. An air gap in a paraxial region is located between every two lens elements of the photographing optical lens system that are adjacent to each other.

Abstract: A projection device to magnify and project, on a screen, an image displayed at an image display element, includes: a dioptric system including at least one positive lens and at least one negative lens; and a reflection optical system having at least one reflection optical element.

Abstract: A zoom lens includes, in order from an object side along an optical axis, a first lens group G1 having positive refractive power, a second lens group G2 having negative refractive power, and a third lens group G3 having positive refractive power. Upon zooming from a wide-angle end state W to a telephoto end state T, a distance between the first lens group G1 and the second lens group G2 increases, and a distance between the second lens group G2 and the third lens group G3 decreases. Given conditions are satisfied. Accordingly, a zoom lens having high optical performance with suppressing variations in aberrations, an optical apparatus equipped therewith, and a method for manufacturing the zoom lens are provided.

Abstract: A system for creating a contiguous digital image of a fluorescence microscope sample. In an embodiment, the system comprises a both a macro camera and a time delay integration (TDI) line scan camera. The system may also comprise a motorized stage, an illumination module, a light source, an excitation filter, an objective lens, an emission filter, and at least one processor configured to assemble a plurality of digital images of portions of the fluorescence microscope sample, generated by the TDI line scan camera, into a contiguous digital image of at least a portion of the fluorescence microscope sample.

Abstract: An imaging system consisting of a cell-phone with camera as the detection part of an optical train which includes other components. Optionally, an illumination system to create controlled contrast in the sample. Uses include but are not limited to disease diagnosis, symptom analysis, and post-procedure monitoring, and other applications to humans, animals, and plants.

Abstract: A 3D localization microscopy system, 4D localization microscopy system, or an emitter tracking system arranged to cause a phase difference between light passing to or from one part of the objective relative to light passing to or from another part of the objective, to produce a point emitter image which comprises two lobes, a separation between which is related to the position of the emitter relative to the objective of the imaging system, and in the 4D system a further property of which image or of said light to or from the objective is related to another location independent property of the emitter.

Abstract: Embodiments of the present invention disclose a terminal device. The terminal device includes a periscope lens. The periscope lens includes a filter, a reflective prism module, a zoom lens, and a sensor, where the filter is configured to filter a light ray transmitted from the outside, and the reflective prism module is configured to reflect twice the light ray into the sensor in combination with the zoom lens, where the light ray is obtained after the filtering by the filter. According to the terminal device in the present invention, a limitation on a thickness of the periscope lens imposed by a width of the sensor can be reduced.

Abstract: A micromirror system that includes a chip frame, at least one spring element, and at least one mirror plate oscillatorily suspended in the chip frame via the at least one spring element. The chip frame and the at least one spring element include at least one microchannel which is provided with an inlet opening and an outlet opening for leading through a flowing coolant.

Abstract: An optical reflecting device includes a mirror part, a pair of joints, a pair of vibration parts, a plurality of driving parts, and a fixed part. Each of the joints has a first end connected to respective one the facing positions to each other on the mirror part and a second end opposite to the first end, and extends along a first axis. Each of the vibration parts has a central portion connected to the second end of respective one of the joints. A plurality of driving parts are disposed in each of the pair of vibration parts, and rotate the mirror part. Both ends of each of the pair of vibration parts are connected to the fixed part. The beam width defined as the length of each of the joints in a direction orthogonal to the first axis is greater than the beam width of each of the pair of vibration parts.

Abstract: Scanning apparatus includes a scanner, which is configured to scan over a field of view falling within a predefined angular range. An interference filter is positioned between the scanner and the field of view and is configured to pass light within a predefined wavelength range that is incident on the interference filter at angles within the predefined angular range, while reflecting the light within the predefined wavelength range that is incident on the interference filter at an angle that is outside the predefined angular range. An ancillary optical element communicates optically with the scanner at a wavelength within the predefined wavelength range via a beam path that reflects from the interference filter at the angle that is outside the predefined angular range.

Abstract: The light deflection unit including a rotary member having a rotor frame formed of a plate of a metal, and a rotary polygon mirror configured to rotate together with the rotor frame and deflect a light beam emitted from a light source, in which a mass of the rotor frame is largest among masses of a plurality of members forming the rotary member, the mass of the rotor frame is smaller than 3 g, and a thickness of the plate of metal is set within a range in which a stress amplitude of a portion of the rotor frame on which a largest stress is exerted during rotation of the rotor member becomes smaller than a fatigue limit of the metal.

Abstract: A head up display can use a catadioptric collimating system. The head up display includes an image source. The head up display also includes a collimating mirror, and a polarizing beam splitter. The light from the image source enters the beam splitter and is reflected toward the collimating mirror. The light striking the collimating mirror is reflected through the beam splitter toward a combiner. A field lens can include a diffractive surface. A corrector lens can be disposed after the beam splitter.

Abstract: A head mounted display (“HMD”) includes a display module that displays a primary viewing image at a focus distance. The display module also displays a focusing cue image at the focus distance to aid a user of the HMD in focusing on the primary viewing image at the focus distance.

Abstract: A head-mounted display comprising a display and a detector. The detector is configured to detect a direction of at least one of the head-mounted display and a line of vision. The display is configured to display an output image of an application, wherein the application is selected based on the direction being outside a range of a front direction.

Abstract: A virtual image display apparatus includes a video image display element which generates video image light and a light guiding member which includes a plurality of optical surfaces and guides the video image light by reflecting on an inner surface side. The light guiding member is a block-shaped member including, as a plurality of optical surfaces, a pair of facing planes which extend substantially in parallel with each other and fully reflect the video image. The light guiding member includes a pair of side portions interposing the pair of facing planes in a direction vertical to a light guiding direction. At least one side portion of the pair of side portions couples the pair of facing planes by a flat plane including a tapered surface which is adjacent to the one plane of the pair of facing planes and forms an obtuse angle.

Abstract: Aspects of the present invention relate to providing see-through computer display optics.

Abstract: In some aspects, a flow cytometer system is provided that includes beam shaping optics positioned to manipulate a light beam and produce a resulting light beam that irradiates the core stream at the interrogation zone of the flow cell. The beam shaping optics include an acylindrical lens positioned to receive and focus light in a direction of a first axis orthogonal to a direction of light travel, and a cylindrical lens positioned to receive the light output from the acylindrical lens and to focus the light output from the acylindrical lens in a direction of a second axis orthogonal to the first axis and to the direction of light travel. The resulting light beam output has a flat-top shaped intensity profile along the first axis, and a Gaussian-shaped intensity profile along the second axis. Related methods of shaping a light beam at an interrogation zone of a flow cell are also provided.

Abstract: A three-dimensional (3D) display system is provided. The 3D display system includes a display device and a switchable grating. The display device is configured to display a set of images with parallax for 3D display. The switchable grating comprises a plurality of switchable grating units, and each switchable grating unit has variable width and variable refractive index and has electric-signal-controllable optical parameters. The switchable grating is coupled with the display device, and configured to enable directional light transmission so as to separate lights of the set of images into predetermined viewing directions to effect the 3D display. Further, the switchable grating includes a first substrate having a plurality of first-type electrodes; a second substrate having at least one second-type electrode; and an optical material contained between the first substrate and the second substrate.

Abstract: A volumetric-image forming system comprises an optical image-forming means 15 and a volumetric display apparatus 17, the optical image-forming means 15 having light-transmitting and plate-like first and second reflecting members 13 and 14 respectively provided with belt-like first and second reflecting surfaces 11 and 12, the first and second reflecting surfaces 11 and 12 being arranged perpendicular to a plate surface and in parallel at a constant pitch, the first and second reflecting surfaces further being arranged crossing one another, the volumetric display apparatus 17 being arranged in the back side of the optical image-forming means 15 and displaying a luminous volumetric image A in a resting or dynamic state inside a display apparatus 16 from electronic data, whereby a volumetric image A inside the display apparatus 16 is formed as a volumetric image B in a free space in the front side of the optical image-forming means 15.

Abstract: A color-changing array that includes a mounting substrate; a plurality of color-changing panels attached to the mounting substrate; and a top polarization layer arranged over, and adapted to move relative to, the plurality of color-changing panels. Each color-changing panel includes: (a) a transparent substrate with a bottom surface and a top surface, (b) a bottom polarization film arranged on the bottom surface of the transparent substrate, (c) a liquid crystal region comprising anisotropic liquid crystal material and configured over the top surface of the transparent substrate, and (d) an optical retardation film arranged over the liquid crystal region and above the top surface. Further, movement of the top polarization layer to a plurality of predetermined positions results in a plurality of corresponding, predetermined visible optical patterns.

Abstract: The present invention provides a lens driving device with image stabilizer function with high driving efficiency of second coils for swinging the lens, and the swing part is light. A lens support accommodating the first coil wound around the Z axis, and a base are respectively connected with first spring components extending along the direction perpendicular to the Z direction. The second coils are wound around the X direction and the Y direction and configured on the outer side of the first coil. A lens carrier and a carrier bracket provided with the second coils are connected with the second spring component extending along the Z direction. The second spring component is supported by the lens carrier and can swing in the X direction and the Y direction.

Abstract: An image blur correction device includes a driving motor that rotates a driven object in an axial rotation direction of a fulcrum axis. The driving motor includes a stator that has either one of a magnet and a driving coil mounted thereon, a first rotor that is positioned to face the stator and has the other of the magnet and the driving coil mounted thereon so as to rotate in a state where the first rotor is attracted toward the stator by magnetic force, a plurality of rolling members that rotates in accordance with rotation of the first rotor and revolves about an axis of rotation of the first rotor, and a second rotor that holds the plurality of rolling members and rotates with the driven object incorporated therein about the axis of rotation of the first rotor in accordance with revolution of the plurality of rolling members.

Abstract: A lens assembly structure of half frame spectacle mainly comprises a half frame having at least one lens mounting portion. At least one lens is to be assembled to the corresponding lens mounting portion with its projections fitted into inlay grooves of the lens mounting portion. Two link assembly cavities are respectively provided on both sides of the half frame within which links can be respectively assembled. Each link has a limit hole provided for passing-through of a fastening member. Each temple is pivotally connected to the corresponding link. The lens can be fixed firmly in the half frame and replaced very easily.

Abstract: Method for determining a progressive ophthalmic lens wherein: a first or a second reference axes (?1, ?2) are determined, the first reference axis being set to a value comprised between [?T?20°, ?T+20°] with ?T being the average axis of astigmatism over a first temporal portion, and the second reference axis being set to a value comprised between [?N?20°, ?N+20°] with ?N being the average axis of astigmatism over a second nasal portion; over the first portion, the sphere value along the first reference axis is superior to the sphere value along a perpendicular axis to the first reference axis (SPH(?1))>SPH(??1)); or over the second portion, the sphere value along the second reference axis is superior to the sphere value along a perpendicular axis to the second reference axis ((SPH(?2))>(SPH(??2)).

Abstract: Apparatus, systems and methods of contact lenses with power sources are provided. In some aspects, a contact lens can include a substrate; and a circuit. The circuit can include: one or more sensors disposed on or within the substrate; circuitry disposed on at least a portion of the substrate; one or more photovoltaic cells disposed on at least a portion of the substrate; and a hybrid power component that supplies at least one of two or more different types of power to the circuitry, wherein at least one of the two or more different types of power is radio frequency/inductive power. In various aspects, other types of power can be solar and/or microelectromechanical system power. Additionally, in various aspects, photovoltaic cells can be arrayed in different configurations and/or over a significant portion of a viewing surface of the contact lens. In some aspects, the photovoltaic cells can be transparent.

Abstract: Conventional optical devices cannot cope with light entering from different directions in different light amounts. An optical device comprises: a transmittance changing unit that is provided in front of an eye of a user, and changes transmittance for light from the outside according to a voltage being applied; and a voltage control unit that controls a voltage to be applied to the transmittance changing unit, wherein by controlling the voltage, the voltage control unit switches between: a first relationship between frontal transmittance that is transmittance for light entering the transmittance changing unit from a frontal direction, and peripheral transmittance that is transmittance for light entering the transmittance changing unit from a direction inclined to the vertical direction relative to an entrance direction of light to which the frontal transmittance applies; and a second relationship between the frontal transmittance and the peripheral transmittance that is different from the first relationship.

Abstract: An integrated optical modulator device. The device can include a driver module coupled to an optical modulator. The optical modulator is characterized by a raised cosine transfer function. This optical modulator can be coupled to a light source and a bias control module, which is configured to apply an off-quadrature bias to the optical modulator. This bias can be accomplished by applying an inverse of the modulator transfer function to the optical modulator in order to minimize a noise variance. This compression function can result in an optimized increased top eye opening for a signal associated with the optical modulator. Furthermore, the optical modulator can be coupled to an EDFA (Erbium Doped Fiber Amplifier) that is coupled to a filter coupled an O/E (Optical-to-Electrical) receiver.

Abstract: Articles comprises iron oxide colloidal nanocrystals arranged within chains, wherein the chains of nanocrystals are embedded within a material used to form the article or a transfer medium used to transfer a color to the article are described. The material or transfer medium includes elastic properties that allow the nanocrystals to display a temporary color determined by the strength of an external force applied to the article, and the material or transfer medium includes memory properties that cause the displayed temporary color to dissipate when the external force is removed, wherein the dissipation of the displayed temporary color is sufficiently slow as to be visually observable by an average observer's unaided eye.

Abstract: An electro-optic modulator device includes a modulation region, a reflecting region, a conductive line and an anti-reflecting region. The modulation region includes a doped region. The reflecting region is over the modulation region. The conductive line is connected to the doped region. The conductive line extends through the reflecting region. The anti-reflecting region is on an opposite surface of the modulation region from the reflecting region.