Abstract: Edge-lit LCD backlight units having a viewable area comprise (a) a downconversion film element, (b) a light guide comprising extraction elements, (c) a reflector and (d) blue LEDs. The extraction elements extend beyond the viewable area.

Abstract: A backlight unit that may be used with a liquid crystal display is presented. The backlight unit includes: a bottom chassis; a light source disposed at an edge of the bottom chassis; a light-converting member disposed on the light source and including quantum dots for changing a wavelength of light emitted from the light source; and a light guide disposed on the bottom chassis adjacent to the light-converting member and positioned to receive light emitted from the light-converting member.

Abstract: A lighting assembly includes a light guide and solid-state light emitters to edge-light the light guide, the light emitters arrayed along a transverse direction. The light guide includes two or more sets of optical elements of well-defined shape. Light output from the lighting assembly by the first and second set of optical elements have a first and a second light ray angle distribution, respectively. The optical elements are configured such that when measured in a plane perpendicular to the light guide and the transverse direction: 1) the first and second light ray angle distributions are significantly narrower than an omnidirectional output distribution; and 2) the peak of the second light ray angle distribution is displaced from the peak of the first light ray angle distribution.

Abstract: A casing integrally includes a first accommodation part in which an optical part is accommodated and a second accommodation part in which an optical support is accommodated. Since the optical part which is a part of an optical plate member formed in a bent plate shape is supported by the optical support which is another part of the optical plate member, it is unnecessary to prepare a thick and robust member for supporting the optical part. That is, the first accommodation part side of a light source device can be made thinner. Moreover, the second accommodation part side of a display apparatus functions as a stand for stationary installation of the first accommodation part side of the light source device. It is therefore possible to reduce the size of the light source device and also the display apparatus, since it is not necessary to attach a separate stand to the first accommodation part side of the light source device.

Abstract: A display device including a liquid crystal panel configured to selectively transmit light for each pixel of the liquid crystal panel; a light guide plate provided behind the liquid crystal panel; a light source array including a plurality of LEDs arranged in a row at first lateral side of the light guide plate, and configured to emit light to the first lateral side of the light guide plate; and a mirror provided in a second lateral side of the light guide plate and configured to reflect the light having reached the second lateral side back along the light guide plate.

Abstract: Provided is a light-emitting unit that includes: a light-guide section having a light entering surface; and a plurality of light sources opposed to the light entering surface of the light-guide section and arrayed in a first direction, and each having an anisotropy in emission intensity. A pattern shape of light applied from any of the light sources to the light entering surface has a shape anisotropy, and the light sources are each disposed to allow a longitudinal direction of the pattern shape to be inclined relative to the first direction.

Abstract: A light-guiding device includes a microstructure layer, a plurality of light-guiding layers and a plurality of intermediary layers. The microstructure layer includes a plurality of microstructure devices. The light-guiding layers are stacked on the microstructure layer. And the intermediary layers are configured on the corresponding light-guiding layer. Furthermore, a reflective index of the light-guiding layer is greater than a reflective index of the upper intermediary layer, one side plane of the light guiding layers defines a inputting-light plane.

Abstract: Provided is a display apparatus, in which a liquid crystal panel and a light guide plate 3 included in a backlight is integrated with a space held by the spacers 5, an optical sheet laminate 4 is arranged in the space between the liquid crystal panel and the light guide plate 3, being positioned by sheet positioning members 6a, and an end of the optical sheet laminate 4 is arranged between a liquid crystal panel attaching portion 52 of the spacer 5 and the light guide plate 3, so that a region exclusively occupied by the optical sheet laminate 4 on the light guide plate 3 is small, allowing a slim bezel of the display apparatus.

Abstract: An illumination apparatus includes: a light-guiding plate; a plurality of light-emitting elements disposed along a side-end surface of the light-guiding plate that serves as a light-entry portion, each of the plurality of light-emitting elements has a light-emitting surface which faces toward the light entry portion; a light source substrate, disposed and separated with a space from the light entry portion of the light-guiding plate when viewed from above, that includes a mounting surface for the plurality of light-emitting elements, the mounting surface being orthogonal to the side-end surface serving as the light entry portion; and a step portion with which an end portion of the light source substrate located toward the light-guiding plate makes contact.

Abstract: The present embodiment relates to a multi-core optical fiber and others having an excellent transmission capacity per unit cross-sectional area and spectral efficiency and being easy to manufacture. The multi-core optical fiber has a plurality of cores, a cladding, and a coating and has an appropriately-set neighboring core pitch, cable cutoff wavelength, confinement index of light into each core, cladding outer diameter, and neighboring intercore power coupling coefficient, and a relationship among a minimum of Formula ?/(rclad?OCTmin), a maximum of the Formula, and a core count is present under a predetermined relationship.

Abstract: A multimode optical fiber may include a core portion formed from SiO2 intentionally doped with a single dopant, wherein the single dopant is phosphorous or a compound of phosphorous. A glass cladding portion may surround and be in direct contact with the core portion. The glass cladding portion may comprise an outer cladding portion and a low-index moat disposed between the core portion and the outer cladding portion. The optical fiber may also have a bandwidth greater than or equal to 2000 MHz-km for each wavelength within a wavelength operating window centered on a wavelength within an operating wavelength range from about 850 nm to about 1310 nm, the wavelength operating window having a width greater than 100 nm. The optical fiber may also have a restricted launch bend loss less than or equal to 0.5 dB/(2 turns around a 15 mm diameter mandrel) at 850 nm.

Abstract: An optical device has a first frame element and second frame element. At least portions of a plurality of optical fiber pairs of an array each including an exposed end are arranged between the two frame elements. A region is defined between opposing surfaces of the two frame elements to hold the optical fibers. When holding the fibers, the two frame elements cooperate to positionally align and orient the exposed ends of each of the optical fibers for at least one of transmitting and receiving light. An optical system with the device includes a TAP photodiode array such that a portion of light is transmitted from at least a pair of input optical fibers to a corresponding pair of photodiodes of the array, and a portion of light is reflected back from an optical filter to output optical fibers corresponding to the input optical fibers.

Abstract: An optical waveguide is provided, which includes a core layer and a cladding layer, wherein at least one of the core layer and the cladding layer is formed from a transparent resin composition containing a phosphorus-containing epoxy resin and a photopolymerization initiator. The optical waveguide and an opto-electric hybrid board including the optical waveguide are excellent in flame resistance, and permit thickness reduction thereof.

Abstract: A photonic integrated circuit is presented that includes a substrate, and a first and second waveguide patterned on the substrate. The first waveguide guides an input beam of radiation. The photonic integrated circuit also includes a coupling region, wherein the first and second waveguides each pass through the coupling region. One or more modulating elements are coupled to each of the first and second waveguides. The first waveguide and the second waveguide have a first facet and a second facet, respectively, and first and second reflections are generated at the first and second facets within the first and second waveguides, respectively. The one or more modulating elements coupled to each of the first and second waveguides are designed to adjust the phase of the first and second reflections before the first and second reflections pass through the coupling region.

Abstract: Methods of depositing materials to provide for efficient coupling of light from a first device to a second device are disclosed. In general, these methods include mounting one or more wafers on a rotating table that is continuously rotated under one or more source targets. A process gas can be provided and one or more of the source targets powered while the wafers are biased to deposit optical dielectric films on the one or more wafers. In some embodiments, a shadow mask can be laterally translated across the one or more wafers during deposition. In some embodiments, deposited films can have lateral and/or horizontal variation in index of refraction and/or lateral variation in thickness.

Abstract: Methods of making optical circuits or waveguides and optical circuits and waveguides made by such methods are disclosed. Optical circuits may include a substrate, a first polymer layer, and a second polymer layer. A first portion of the first polymer layer has a higher refractive index than a second portion of the first polymer layer. Optical waveguides may include a first polymer layer on a surface of a substrate. A first portion of the first polymer layer has a higher refractive index than a second portion of the first polymer layer.

Abstract: A splicer and a method for fusion-splicing optical fibers are provided, in which the disconnection of a fusion spliced portion of optical fibers can be prevented when the windbreak cover is opened upon fusion splicing. A method for fusion-splicing optical fibers includes: holding optical fibers on optical fiber holders which are arranged on a pair of movable stages, respectively and covering the holders with a windbreak cover; and butting the optical fibers each other by bringing the pair of movable stages mutually closer; fusion-splicing the butted optical fibers together; and loosening, before opening the windbreak cover 4, the tension applied to optical fibers between the fiber holding parts and positions at which the windbreak cover contacts with the optical fibers.

Abstract: A method for fusion-splicing optical fibers and a fusion splicer are provided, which enable preventing a fusion spliced portion from disconnecting when the optical fiber is removed from the fusion splicer. A fusion-splicing method for optical fibers comprises: holding optical fibers and on optical fiber holding parts respectively provided on a pair of movable stages; butting ends of optical fibers by bringing the pair of movable stages mutually closer; fusion-splicing butted optical fibers to form a fusion spliced portion S; carrying out a proof test, the proof test including applying a tension to the fusion spliced portion S by moving the pair of movable stages so as to distance them from each other; and bringing the pair of movable stages mutually closer by a predetermined distance upon completion of the proof test.

Abstract: An integrated optical coupler device comprising, on a substrate surface: an integrated optical coupling grating extending in lateral directions parallel to the substrate surface and which, by diffraction at its grating structures, either converts electromagnetic waves, guided parallel to the substrate surface, of at least two waveguide modes of integrated optical waveguides into fiber modes propagating perpendicularly to the substrate surface, or converts electromagnetic waves, propagating perpendicularly to the substrate surface, of a fiber mode into electromagnetic waves, propagating parallel to the substrate surface, of at least two waveguide modes, and a first conductor pair, connected to the coupling grating and formed by a first and a second integrated optical waveguide, through which, in mutually opposite first and second directions parallel to the substrate surface, electromagnetic waves of at least two waveguide modes can be conducted to the coupling grating or can be conducted away from the coupling

Abstract: In various embodiments, a beam-parameter adjustment system and focusing system alters a spatial power distribution of a plurality of radiation beams before the beams are coupled into an optical fiber.

Abstract: A bi-directional optical module that provides an Rx unit and a Tx unit, where optical axes are perpendicular to each other, is disclosed. The optical module provides a housing that installs a WDM filter therein and assembles the coupling unit in a surface through the front alignment unit, the Tx unit in another surface opposite to the former surface, and the Rx unit in still another surface connecting the former two surfaces through the rear alignment unit. The axes of the Tx unit and the coupling unit are in parallel to each other, but the axis of the Rx unit is in perpendicular to the former two axes. The Rx unit installs a photodiode (PD) with an optically sensitive surface leveled with the surface of the rear alignment unit to which the Rx unit is attached.

Abstract: A method for fabricating a resonator structure, comprising engineering dispersion of electromagnetic radiation guided along a boundary of an axially symmetric substrate, the engineering comprising micro-structuring a geometry of the boundary, wherein the structure defines a waveguide for electromagnetic radiation.

Abstract: An optical device includes an optical reflector based on a coupled-loopback optical waveguide. In particular, an input port, an output port and an optical loop in arms of the optical reflector are optically coupled to a directional coupler. The directional coupler evanescently couples an optical signal between the arms. For example, the directional coupler may include: a multimode interference coupler and/or a Mach-Zehnder Interferometer (MZI). Moreover, destructive interference during the evanescent coupling determines the reflection and transmission power coefficients of the optical reflector.

Abstract: Embodiments herein describe disposing a waveguide adapter onto an SOI device after the components on a silicon surface layer have been formed. That is, the waveguide adapter is disposed above optical components (e.g., optical modulators, detectors, waveguides, etc) formed in a surface layer. In one embodiment, a waveguide in a bottom layer of the waveguide adapter overlaps a silicon waveguide in the surface layer such that the silicon waveguide and the waveguide in the bottom layer are optically coupled. The waveguide adapter also includes other layers above the bottom layer (e.g., middle and top layers) that also contain waveguides which form an adiabatic optical system for transmitting an optical signal. At least one of the waveguides in the multi-layer adapter is exposed at an optical interface of the SOI device, thereby permitting the SOI device to transmit optical signals to, or receive optical signals from, an external optical component.

Abstract: An optical module includes a waveguide interconnect that transports light signals; a Silicon Photonics chip that modulates the light signals, detects the light signals, or both modulates and detects the light signals; a coupler chip attached to the Silicon Photonics chip and the waveguide interconnect so that the light signals are transported along a light path between the Silicon Photonics chip and the waveguide interconnect; and one of the Silicon Photonics chip and the coupler chip includes first, second, and third alignment protrusions. The other of the coupler chip and the Silicon Photonics chip includes a point contact, a linear contact, and a planar contact. The point contact provides no movement for the first alignment protrusion. The linear contact provides linear movement for the second alignment protrusion. The planar contact provides planar movement for the third alignment protrusion.

Abstract: Embodiments include a high bandwidth optical connection system suitable for interconnecting servers, for example within a rack of a datacenter. An edge mount optical connector assembly includes an edge-mount housing providing topside socket contacts proximate to a first end of the housing and a port at a second end to receive an optical plug connector. A socket latch cantilevered from an anchor point on the housing includes a latching face to contact a keeper face disposed on the housing and a spring load application surface between the anchor point and the latching face to apply a spring force against the electrical contacts for retention of a removable optical transceiver module. An optical plug connector includes a front housing joined to a rear housing with a plug lens spring loaded within the housing and with alignment features comprising two flat alignment surfaces orthogonally oriented relative to each other.

Abstract: An optical connector connectable to another optical connector includes an optical waveguide that includes a core, an attachment part to which the optical waveguide is attached, a lens part in which a positioning hole is formed, and a positioning pin that is provided on the attachment part and inserted through the positioning hole. The lens part and the attachment part are joined with the positioning pin being inserted into the positioning hole.

Abstract: A passive optical circuit breaker includes a substrate and an optical waveguide assembly arranged relative to the substrate. The optical waveguide assembly includes a first optical waveguide portion having a first low-loss portion and a first high-loss portion, and a second optical waveguide portion having a second low-loss portion. The first low-loss portion and the second low-loss portion define a first optical path through the optical waveguide assembly, and optical energy directed through the first high-loss portion exceeding a prescribed threshold causes the first optical waveguide portion to physically deflect relative to the second optical waveguide portion and interrupt the first optical path through the optical waveguide assembly.

Abstract: A modular connector system for various types of different fiber optic and/or electrical connectors may include a connector having a housing configured to accommodate various different configurations of inserts that are configured to hold different types of either fiber optic connector, electrical connectors, or a combination of fiber optic and electrical connectors.

Abstract: In an optical connector fitting structure, a first optical connector includes a first fixing member which fixes a first optical fiber to a first housing by being attached to the first housing while its locking state is changed from a temporarily locked state to an actually locked state, and a second optical connector includes a second fixing member which fixes a second optical fiber to the second housing by being attached to the second housing while its locking state is changed from a temporarily locked state to an actually locked state.

Abstract: A multicore fiber alignment apparatus is described, having a chassis into which is mounted ferrule-holding means for holding a multicore fiber ferrule having one or more capillaries extending therethrough. Fiber-holding means for holding one or more multicore fibers in position to be mounted into the ferrule, such that each multicore fiber extends through a respective ferrule capillary. Means are provided for monitoring the rotation angle of each multicore fiber within its respective capillary, relative to a reference rotational orientation. Means are further provided for rotating each of the multicore fibers within its respective capillary. The rotational orientation of each multicore fiber is fixed when its rotation angle is equal to zero.

Abstract: To improve the termination of a fiber optic cable, disclosed is an overboot assembly for a fiber optic terminus that retains a terminal end of the fiber optic cable in a receptacle. The overboot assembly provides strain relief to the fiber optic cable. Also, the overboot includes a removal member that is not separable from a fiber optic assembly of the fiber optic cable, the terminus and the overboot. The removal member may be advanced longitudinally relative to the terminus to manipulate a retaining member in the receptacle that latches the terminus in a connected state with the receptacle. Manipulation of the retaining member unlatches the terminus so that the terminus may be removed from the receptacle.

Abstract: A fiber optic connector having a radio frequency identification tag and an optical fiber connection device are disclosed in the embodiments of the present invention. The fiber optic connector comprises: a housing (1); a tail sleeve (4) partly inserted in the housing from a first end of the housing and configured to fix an end of an optical fiber cable (20); a tag receiving portion (5) which is formed in a sidewall of the housing, on a radial outside of the tail sleeve and in which the radio frequency identification tag (10) is disposed; and an electromagnetism restriction part (15) disposed between the tag receiving portion and the tail sleeve to restrict an electromagnetic influence of the tail sleeve made of a metal material on the radio frequency identification tag.

Abstract: A portion of an optical waveguide extending laterally within a photonic integrated circuit (PIC) chip is at least partially freed from the substrate to allow physical displacement of a released waveguide end relative to the substrate and relative to an adjacent photonic device also fabricated in the substrate. The released waveguide end may be displaced to modulate interaction between the photonic device and an optical mode propagated by the waveguide. In embodiments where the photonic device is an optical coupler, employing for example an Echelle grating or arrayed waveguide grating (AWG), mode propagation through the coupler may be modulated via physical displacement of the released waveguide end. In one such embodiment, thermal sensitivity of an integrated optical wavelength division multiplexer (WDM) is reduced by displacing the released waveguide end relative to the coupler in a manner that counters a temperature dependence of the optical coupler.

Abstract: An optical package includes a laser die a photonics die. The laser die generates light and includes a laser facet that emits light. The photonics die modulates light emitted from the facet and includes an internal waveguide optically connected with the facet and one or more standoff contacts, flush contacts, or reduced contacts. The optical package may also include an external waveguide optically connected to the photonics die. The external waveguide may be optically connected to the photonics die prior to electrically connecting the photonics die with an interposer. The standoff contacts extend from a device side of the photonics die beyond the laser die, the flush contacts extend from the device side of the photonics die to be coplanar with the laser die, and the reduced contacts extend from the device side of the photonics short of the laser die.

Abstract: A semiconductor integrated circuit that reduces a loss in an electrical signal and a method for manufacturing the semiconductor integrated circuit are provided. The semiconductor integrated circuit comprises a first region on which an optical circuit is to be formed and a second region on which an electrical signal wiring is to be formed. The first region comprises an Si substrate (502), a BOX layer (504) formed on the Si substrate (502), a first SOI layer (506) formed as an optical circuit on the BOX layer (504), and a first SiO2 layer (508) formed on the first SOI layer (506). The second region comprises the Si substrate (502), the BOX layer (504), a second SiO2 layer (508) formed on the BOX layer (504), and an electrical signal wiring (510) formed on the second SiO2 layer (508).

Abstract: An optical component including a multi-layer substrate, an optical waveguide element, and two optical-electro assemblies is provided. The multi-layer substrate includes a dielectric layer, two circuit layers, and two through holes passing through the dielectric layer. The optical waveguide element is located on the multi-layer substrate and between the through holes. The optical-electro assemblies are respectively inserted into the corresponding through holes and correspondingly located at two opposite ends of the optical waveguide element. One of the optical-electro assemblies transforms an electrical signal into a light beam and provides the light beam to the optical waveguide element, and the other one of the optical-electro assemblies receives the light beam transmitted from the optical waveguide element and transforms the light beam into another electrical signal. A manufacturing method of the optical component and an optical-electro circuit board having the optical component are also provided.

Abstract: A hermetically sealed media converter apparatus configured to operate in harsh high-pressure differential environments, such as deep marine environments, and oil and gas. A hermetically sealed media converter apparatus is provided having a vessel forming an inner chamber that is hermetically sealed from surrounding ambient environment outside the vessel. Media conversion circuitry is contained within the inner chamber. At least one hermetic electrical feedthrough is mounted on the vessel enabling a transmit wire and a receive wire to pass therethrough and connect to the media conversion circuitry, while maintaining the hermetic seal of the inner chamber of the vessel from the surrounding ambient environment. Similarly, a hermetic optical feedthrough also is mounted on the vessel enabling an optical fiber to pass therethrough and connect to the media conversion circuitry, while maintaining the hermetic seal of the inner chamber of the vessel from the surrounding ambient environment.

Abstract: An optical transceiver of the CFP type having a gasket set within the slot is disclosed. The optical transceiver provides the slots in respective sides of the housing to pass the screws therein for fastening the optical transceiver to an electrical plug prepared in the host system. A support is also set within the slot so as to extend along the outer wall of the slot and not to interfere with the screw. The support pushes the gasket against the outer wall so as to cover a gap inherently formed between the top housing and the bottom housing.

Abstract: The optical includes a waveguide positioned on a base and an optical component positioned on the base. The optical component is a light sensor that includes an active medium or a modulator that includes an active medium. The waveguide is configured to guide a light signal through the component such that the light signal is guided through the active medium. The device includes one or more heat control features selected from the group consisting of: placing one or more thermal conductors over a lateral side of a ridge of the active medium; extending thermal conductors from within the active component to a location outside of the active component, and tapering the ridge of the active medium within the perimeter of the active component.

Abstract: An inventive opto-electric hybrid board includes: opto-electric module portions respectively defined on opposite end portions of an elongated insulation layer, and each including a first electric wiring of an electrically conductive pattern and an optical element provided on a front surface of the insulation layer; and an interconnection portion defined on a portion of the insulation layer extending from the opto-electric module portions, and including an optical waveguide optically coupled with the optical elements. A metal reinforcement layer provided on a back surface of the insulation layer extending over the opto-electric module portions into the interconnection portion. A portion of the metal reinforcement layer present the interconnection portion has a smaller width than the opto-electric module portions, and the smaller width portion has rounded proximal corners.

Abstract: An example embodiment includes a pluggable active optical cable connector configured to permanently maintain engagement of an optical interface included in an optoelectronic module. The pluggable active optic cable connector includes a lens connection section which connects a plurality of optical fibers to the optical interface, a latching portion which engages with a latch receiving portion of the optoelectronic module, the latching portion including a first engagement portion which engages with an optoelectronic engagement portion of the optical interface and a second engagement portion, and a locking portion which engages with the second engagement portion of the latching portion and locks the lens connection section in place with respect to the optoelectronic module as a plug insertion force is applied to the pluggable active optical cable connector so as to prevent the lens connection section from disengaging from the optical interface of the optoelectronic module.

Abstract: An example embodiment includes a pluggable active optical cable product configured to maintain engagement of an optical interface included in an optoelectronic module. The pluggable active optical cable product includes a lens connection section which connects a plurality of optical fibers to the optical interface, a clip configured to surround the lens connection section and the optical interface so as to apply a compressive force which urges the lens connection section to connect to the optical interface, an bottom shell which houses the lens connection section, optical interface, and clip, and an upper shell which is configured to be disposed on a surface of the bottom shell when assembled with the bottom shell so as to form an enclosure for the lens connection section, the optical interface, and the clip.

Abstract: A photonic integrated circuit is provided. The photonic integrated circuit includes a substrate having a through hole interconnecting a first surface and a second surface; a transmission wire passing through the through hole and including an optical transmission structure and an electrical transmission structure; and an optical-to-electrical converter connected to the optical transmission structure of the transmission wire on the first surface.

Abstract: An optical communication cable bundle is provided. The bundle includes a bundle jacket and a plurality of optical fiber subunits surrounded by the bundle jacket. Each optical fiber subunit includes a subunit jacket defining a subunit passage and a plurality of optical fibers located with the subunit passage. The thickness of the bundle jacket may be less than a thickness of each of the subunit jackets. The tensile strength of the bundle jacket may be less than the tensile strength of the subunit jacket, and the tear strength of the outermost bundle layer may be less than the tear strength of the subunit jacket. The subunit jacket may be formed from a fire resistant material that has an oxygen limiting index that is greater than an oxygen limiting index of the material of the bundle jacket.

Abstract: An optical-fiber ribbon with reduced-diameter optical fibers is disclosed in which the optical-fiber ribbon comprises a plurality of reduced-diameter optical fibers that meet the ITU-T G.657.A1 standard or the ITU-T G.652.D standard, and a ribbon matrix surrounding the reduced-diameter optical fibers, wherein a local matrix thickness of the optical-fiber ribbon is more than about 35 microns.

Abstract: A self-locking cable clamp arrangement includes a bracket and a flexible tab disposed on the bracket. The bracket has a cable mounting region, a first engagement region, and a support region disposed therebetween. A cable can be clamped to the cable mounting region. The support region defining two members spaced apart sufficient to enable an edge of the panel to extend partially therebetween. The flexible tab can be selectively coupled to the cable mounting region and to the first engagement region. The clamp arrangement mounts to the panel by sliding the bracket downwardly through an open-ended slot defined in the panel until the tab is received within a cutout portion of the panel to secure the bracket to the panel.

Abstract: Techniques for micro-optics alignment and assembly are described. By attaching a needle pin to an optical component to be assembled, the optical component can be placed and aligned within a limited space. After the aligned optical component is permanently bonded to a substrate or to another component, the needle pin is detached from the component. This technique allows a user to place and align a small optical component to a right position.

Abstract: An adjustable support assembly for an object to be accurately positioned relative to a base, in particular for a secondary mirror of an optical mirror telescope, has at least one support structure connected to the base and to the object. The support structure has at least two struts extending in a non-parallel manner relative to each other, where each strut has associated therewith a drivable actuator element in such a way that the actuator element applies a force onto the strut that deflects the strut transversely to the longitudinal extension thereof. The support structure may be supported in an articulated manner relative to the base.

Abstract: The present technology relates to an imaging apparatus and method, and a program, capable of focusing on a subject with higher accuracy. An image sensor shoots a captured image by receiving light coming from a subject via an optical unit and by converting the light into electrical signal. A captured-image processing unit detects a luminance level of the captured image. A passive mode AF calculator calculates a shift amount of a lens in autofocusing using a passive mode, and an active mode AF calculator calculates a shift amount of a lens in autofocusing using an active mode. An AF mode determination unit selects any one of the passive mode or the active mode by comparing the luminance level with a threshold. The present technology is applicable to digital still cameras.