Abstract: A solid immersion lens supporting device includes a lens holder 30 that holds a solid immersion lens 20 in a free state in which a lens bottom surface 22 protrudes downward through a lower opening 32 so as not to fix the solid immersion lens, and a lens cover 40 which is provided to an upper opening 31 of the lens holder 30, and in which a cover bottom surface 42 on the solid immersion lens 20 side is on a plane perpendicular to an optical axis, the lens cover coming into one-point contact with a spherical lens top surface 21 of the solid immersion lens 20. Further, the lens cover 40 is provided with a positioning portion which is capable of carrying out positioning of the solid immersion lens 20 with respect to the objective lens with reference to an image of the lens cover 40 observed via the objective lens. Thereby, the immersion lens supporting device which is capable of efficiently carrying out movement, installation, and positioning of the immersion lens onto a sample is realized.

Abstract: A lens support frame includes an annular body portion; a large diameter lens holding groove on an inner peripheral surface of the body portion which is open on one side; a small diameter lens holding groove formed on an inner peripheral surface of the body portion and is open on the one side; and large-diameter-groove and small-diameter-groove lens-bonding depressions formed on inner peripheral surfaces of a large diameter lens holding groove and the small diameter lens holding groove, respectively, and allow an adhesive to be injected into the large-diameter-groove and small-diameter-groove lens-bonding depressions through end openings thereof on the one side, the end opening of the small-diameter-groove lens-bonding depression being communicatively connected with the large-diameter-groove lens-bonding depression. Circumferential positions of the large-diameter-groove and small-diameter-groove lens-bonding depressions are mutually different.

Abstract: An optical apparatus is disclosed which is capable of adjusting spacing between an optical member and a holding member or between optical members virtually without changing irradiation conditions of laser, and thus achieving reduction of joining time and improvement of positional accuracy at low cost. The apparatus includes an optical member, a thermomelting member, a spacing adjustment member and a holding member in this order. A first weld portion welding the spacing adjustment member and the holding member is formed therebetween, the first weld portion having been formed by heat generation of the holding member irradiated with the laser light transmitted through the optical member, the thermomelting member and the spacing adjustment member, and a second weld portion welding the spacing adjustment member and the optical member is formed therebetween, the second weld portion having been formed by the thermomelting member melted with heat transferred from the holding member.

Abstract: A lens attaching/detaching device includes a lever holding plate that has an elastic piece which presses a lock releasing lever in a direction away from a locking mechanism and holds the lock releasing lever while the lock releasing lever is guided by a lower case. The lock releasing lever includes a first sliding part and a second sliding part which are guided by the lower case. The first sliding part and the second sliding part are arranged at different positions in a Z direction and an X direction orthogonal to a Y direction. An operation part is disposed at the same position as that of the first sliding part in the Z direction. An actuation part is disposed at the same position as that of the second sliding part in the Z direction. The lower case includes a first guiding part which guides the first sliding part and the second guiding part which guides the second sliding part.

Abstract: A displacement mechanism, a lens module using the same and a device using the same are provided. The displacement mechanism of lens module comprises a base, a first element and a second element. The first element is disposed on the base, wherein the first element is immovably disposed relative to the base along a first direction and movably disposed relative to the base the base along a second direction. The second element is disposed on he base, wherein the second element is movably disposed relative to the first element along the first direction and movably disposed relative to the base along the first direction and the second direction.

Abstract: Disclosed herein is a wide display with a lens. The lens is provided on the front of a display unit so that a display unit protection member which is provided on the perimeter of the display unit can be optically hidden by an optical illusion effect induced by the lens and without changing the structure of the display unit. Further, an image displayed on the display unit can look smoother, and the image can be displayed in such a way that it looks wider. Moreover, the present invention can improve the satisfaction of customers who want to increase the size of an image displayed on the display unit. Furthermore, the present invention can reduce the burden of an enormous investment in equipment that is required to produce display units due to the recent trend of increasing size.

Abstract: A lens barrel 111 according to the present invention includes: a lens group 220 which moves along an optical axis direction 300; and a lens holding frame 224 holding a lens group 220. A guide hole 406 is provided in the lens holding frame 224, the guide hole 406 being penetrated by a main shaft 440 having a circular cross section. A cross section of the guide hole 406 taken orthogonal to a longitudinal direction of the main shaft 440 includes at least two linear portions 406a, and the main shaft 440 is in contact with the two linear portions 406a.

Abstract: Element, panel and direct solar radiation collecting and concentrating system by means of panels with collecting and concentrating elements which are allowed freedom of movement during diurnal and seasonal sun tracking. The elements in question incorporate a primary lens concentrating direct radiation. The element includes hollow compartments which contain a given fluid at a given pressure. The lower section includes a secondary lens and/or internally reflexive conical element allowing the introduction of radiation, in parallel, into tubes or optical fibre, or irradiation onto radiation converting systems. The movement of the device is produced by fluid heating and pressure in the side compartments. This pressure is communicated to the axes via pistons which cause the device to rotate in search of the optimal position with a view to optimizing its focus on the secondary lens.

Abstract: An optical encoder includes a detection head. The detection head includes an optical system including a lens including a pair of bosses integrally formed with the lens and disposed with an optical axis of the lens therebetween, and an aperture plate having a pair of reference-pin-insertion holes disposed with an aperture therebetween; a housing including a pair of attachment portions and having a pair of lens-boss-insertion holes and a pair of reference-pin-insertion holes disposed on a central symmetry plane; a lens holder having a pair of lens-boss-insertion holes and a pair of reference-pin-insertion holes disposed on the central symmetry plane; and a pair of reference pins for positioning the lens holder and the aperture plate relative to the housing. An optical axis of the optical system is adjusted with respect to the bosses and the reference pins.

Abstract: An image alignment device for tandem optics (IAD-TO) is disclosed which provides a standalone means for the operator to align and optimize the imagery produced by dissimilar optical devices to achieve overall system capability gain. The IAD-TO is inserted into the optical path between the optical devices when they are configured for in line use and provides the operator an on-demand capability to compensate for the inherent image shift between them, especially for those optical devices that provide no alignment adjustment mechanisms. Featuring interchangeable adaptor arms and quick action mount interfaces, the IAD-TO can be used with various types of optical devices and can be mounted to a variety of surfaces.

Abstract: A compact and thin lens module that uses a flat-plate-shaped displacement device to drive a lens, and a compact, thin imaging apparatus and electronic system using the lens module.

Abstract: A spacing ring is provided and includes a peripheral ring-shaped spacing portion and a light shading portion extending from an inner peripheral surface of the spacing portion. The spacing portion has a resisting surface. The light shading portion includes an inclined clamping surface connecting with the resisting surface of the spacing portion. The clamping surface and a central axis of the spacing ring cooperatively define an acute angle, the clamping surface and the resisting surface of the spacing portion cooperatively define an obtuse angle. A lens module using the spacing ring is also provided.

Abstract: An optical element unit is provided comprising an optical element group for projecting light along an optical axis of the optical element group and a housing having an inner housing part partly defining a first space and a light passageway between the inner housing part and a second space. The inner housing part receives the optical element group. The optical element group comprises an ultimate optical element located in the region of the light passageway. A load-relieving device is provided adjacent to the ultimate optical element, the load relieving device partly defining the first space and the second space and at least partly relieving the ultimate optical element from loads resulting from pressure differences between the first space.

Abstract: Disclosed is a motor for driving lenses. The motor includes a case, a yoke fixed in the case, a magnet fixed in the yoke, a carrier equipped with lenses and installed in the magnet such that the carrier moves up and down within the magnet, a coil coupled with the carrier, a spring unit including first and second springs having arc shapes and being separated from each other while forming a ring shape as a whole, a spacer supporting an outer peripheral surface of the spring unit, and a terminal provided on the spacer, in which one side of the terminal protrudes downward by passing through a bottom of the case to make connection with the spring unit and a main PCB of a product.

Abstract: A fixing structure for fixing an optical element at a predetermined position in an optical device, the fixing structure has a plurality of first pressing members to fix the optical element at at least two positions on a surface of the optical element orthogonal to an optical axis of the optical element and a second pressing member to fix the optical element at a predetermined position on a surface of the optical element to the optical axis. A depth of pressing of the surface of the optical element by a tip of the second pressing member is larger than the depth of pressing of the surface of the optical element by the tips of the first pressing members.

Abstract: An optical layer stack having a first layer, a second layer, a first spacer part associated with the first layer and a second spacer part associated with the second layer, wherein the two spacer parts have groove and tongue for an engagement in a stacking direction of the optical layer stack in order to provide a connection between the first and the second spacer part and a spacing of the first and the second layer in stacking direction.

Abstract: In one embodiment, an optical lens assembly comprising a primary lens and an optical structure located at an outer portion of the lens is disclosed. The primary lens is configured to direct a substantial amount of light to a predetermined first distance whereas the optical structure is configured to direct light towards a second distance that is relatively close to the optical lens assembly compared to the first distance. Other embodiments disclose light-emitting devices and proximity sensors having such an optical lens assembly. Alternative embodiments of the optical lens assembly are disclosed, including but not limited to an optical structure defining an optical surface located at a lens flange and optical structure defining a light guide located at a base portion of the optical lens assembly.

Abstract: When it is detected that a solid immersion lens comes into contact with the semiconductor device, the lens is caused to vibrate by a vibration generator unit. Next, a reflected light image from the lens is input to calculate a reflected light quantity of the reflected light image, and it is judged whether a ratio of the reflected light quantity to an incident light quantity is not greater than a threshold value. When the ratio is greater than the threshold value, it is judged that optical close contact between the lens and the semiconductor device is not achieved, and the lens is again caused to vibrate. When the ratio is not greater than the threshold value, it is judged that optical close contact between the lens and the semiconductor device is achieved, and an observed image of the semiconductor device is acquired.

Abstract: The present invention relates to a camera module mounted with an external look-forming holder improved in heat emission function, the camera module including: a housing; a lens insertion hole opened toward an upper surface of the housing for insertion of a lens; a filter attachment unit formed on a floor surface of the housing for attaching a filter; and a heat emission outlet formed on an upper surface of the lens insertion hole in an upper-wide/bottom-narrow shape, wherein a heat emission outlet is formed at an upper surface of a lens insertion hole to induce heat generated from inside of a housing to be emitted to outside along an inner side of the heat emission outlet.

Abstract: The disclosure provides a positioning unit for an optical element in a microlithographic projection exposure installation having a first connecting area for connection to the optical element, and having a second connecting area for connection to an object in the vicinity of the optical element.

Abstract: A method for assembling a lens module is provided. The lens module includes a lens barrel, a lens holder, a lens and a filter. The lens barrel includes a first portion and a second portion. The method for assembling the lens module includes the steps of; providing a tray which defines a plurality of perforations, each of which is for accommodating the lens barrel; spreading glue on the second portion, and affixing the filter on the second portion by means of glue; solidifying the glue; cleaning the inside of the lens barrel after the filter is mounted on the second portion; cutting the filter into a plurality of filter portions whose shape matches the shape of the second portion; and placing the lens holder with the lens into the lens barrel complete with a filter portion after the lens barrel has been cleaned.

Abstract: A lens module includes a lens barrel, a number of lenses, a number of opaque plates, and a filter glass. The barrel, the lenses, the opaque plates, and the filter glass all are received in the lens barrel. Each opaque plate is sandwiched between two adjacent lenses. Each lens includes an imaging portion and a non-imaging portion surrounding the imaging portion for engaging an inner sidewall of the lens barrel. The filter glass is arranged closer to an image-side of the lens module than the lens and the opaque plates. The projection of one of the opaque plates arranged closest to the filter glass, along the direction of incident light of the lens module, totally covers the non-imaging portion of the lens arranged closest to the filter glass.

Abstract: There is provided an optical pickup actuator for actuating a lens holder having an object lens according to an interaction between coils and magnets. The optical pickup actuator includes a lens-seating portion formed on the lens holder to support the object lens and a lens guide portion protruding from the lens-seating portion to securely support the object lens. The lens guide portion has an adhesive confining groove in which adhesive can be injected to securely fix the object lens.

Abstract: A lens barrel includes a lens frame, a guide shaft, a lead screw, a nut, and a biasing spring. The guide shaft is inserted into the lens frame. The nut is threaded onto the lead screw. The biasing member biases the lens frame toward the nut. The lens frame includes a first bearing component having a first insertion hole and a second bearing component having a second insertion hole. The guide shaft hits an inner peripheral face of the first insertion hole at a first and second contact point, and hits an inner peripheral face of the second insertion hole at a third and fourth contact point. The first and second contact points are disposed on opposing side of the third and fourth contact points using as a reference a parallel plane which extends along the direction of an optical axis and passes through a guide axis.

Abstract: A lens plate includes a transparent substrate wafer, and a plurality of lenses and spacers that are formed of a single portion of material on the transparent substrate wafer. An assembly includes a first lens plate that includes a first transparent substrate wafer, a plurality of first lenses and a plurality of spacers, the first lenses and spacers being formed of a single portion of material on said first transparent substrate wafer. The assembly also includes a second lens plate that includes a second transparent substrate wafer and a plurality of second lenses formed thereon, each of the plurality of second lenses corresponding to a respective one of the plurality of first lenses. The lens plates are aligned such that each of the plurality of first lenses aligns with the respective one of the plurality of second lenses, and the lens plates are bonded to one another.

Abstract: Adjustable mounts for optical elements or the like that may include absolute position information feedback. For some embodiments, position data may be generated independent of displacement measurement. Position data feedback may be provided to driver embodiments, such as piezoelectric inertia drivers, by a controller and used to achieve a desired position setting for an adjustable mount.

Abstract: Techniques are disclosed for systems and methods to provide thermal despace compensation for optics assemblies, such as devices including one or more lenses and/or optical devices. A thermal despace compensation system may include one or more interfaces substantially situated between optical devices that expand and contract with changing temperature according to their coefficients of thermal expansion (CTEs). Each interface may be implemented with one or more shapes and/or interfaces adapted to provide a compensation despace to compensate for thermal expansion and contraction and/or reduce optical defects caused by changes in temperature of the various optical devices.

Abstract: A magnification system for magnifying a surface of a device is provided. The magnification system includes a magnifying lens having a ridge portion extending along one of the edges and securing means for securing the magnifying lens on or above the surface of the device. An example of such a device is a mobile phone. The securing means further includes a base adapted to mount to a surface of the device, an arm pivotally connected to the base with a first connector, a clamp including a channel therein for receiving and slidably holding the ridge portion of the magnifying lens and a second connector for pivotally connecting the arm to the clamp. The second connector further includes a slider member having a groove and means for attaching the lens to the slider member. The slider member further includes a first pivotally connected part and a second pivotally connected part. The slider member moves along the groove and further is being attached to the first pivotally connected part.

Abstract: According to an illustrative embodiment, a lens unit is provided. The lens unit includes at least one lens having an engagement portion in a flange portion of the lens, the engagement portion having a width perpendicular or substantially perpendicular to the optical axis of the lens, and the width of the engagement portion decreasing as the engagement portion is traversed in a direction parallel or substantially parallel to the optical axis of the lens.

Abstract: Techniques described herein generally relate to optical devices and methods of manufacturing optical devices. An example optical device includes a first substrate having a first optical element, a second substrate coupled to the first substrate, and cured resin. The first substrate has a first optical element. The second substrate has at least one supporting structure and a second optical element supported by the at least one supporting structure. The at least one supporting structure has at least one receptor. The cured resin is arranged in the at least one receptor of the at least one supporting structure effective to position the second optical element relative to the first optical element.

Abstract: A panorama lamp with 360 degree peripheral illumination with reference to an axis of the lamp is disclosed. Each of the light units mounted on a heat sink has a light chip facing outward from the lamp. Either a protection cap or a circular wall lens can be optionally adopted to cap the top of the lamp. The protection cap provides protection to the chips of the lamp from being damaged. The circular wall lens modifies the beam profile of the lamp to meet various market requests.

Abstract: The invention relates to a monolithic optical mount, which is divided by a plurality of cutouts into a stationary outer mount ring, a laterally adjustable inner mount ring, and manipulator units that are arranged with uniform offset from each other and formed by the remaining material connections. The cutouts have a uniform constant width and can therefore advantageously be produced by milling. The manipulator units have a simple geometrical design in the form of T- or L-shaped webs.

Abstract: The subject of the present invention is a lens-holder device (1) intended to be hooked onto a support (101) of determined direction belonging to a conveyor carriage intended for transporting optical lenses (10) so that an optical test can be carried out on said optical lenses following a treatment of said optical lenses, said lens-holder device (1) comprising a body (2), suspension means (3) for suspending from the support (101) which are connected to the body (2), retaining the means (4) for keeping an optical lens (10) in position on the lens-holder device (1), which are connected to the body (2), these retaining means (4) comprising support means (5) defining at least one first resting point (a) for the optical lens (10), elastic return means (6) defining at least two further resting points (b, c) for the optical lens (10), the various resting points (a, b, c) defining a location for the optical lens (10), the body of the lens-holder device (1) being shaped in such a way as to pass around the portions of s

Abstract: A support system for a vibrating component of an optical assembly that is adjacent to a frame, wherein the component is driven to vibrate along an X-direction of a three-dimensional Cartesian coordinate system. The support system includes a support member connected to the frame. The support system has contact elements that are adjustable for movement into and out of contact with the vibrating component to constrain motion of the vibrating component in the Y-direction and in the Z-direction, without constraining motion of the vibrating component in the X-direction.

Abstract: A method of tuning a mold for an optical component, said method comprising: (a) molding an optical component comprising at least: (i) a body portion defining a first face; (ii) at least one optical element on said first face, said optical element having a certain geometry; (iii) at least one alignment element on said first face selected from one of an alignment hole or an alignment pin; and (iv) at least one inspection element in a position fixed relative to said at least one alignment element on said first face; (b) measuring the location of said inspection element on said front face relative to said optical element; (c) comparing said location to a standard to determine a difference; and (d) if said difference is significant, adjusting a component of said mold to change said location of said alignment element relative to said optical element and reiterating steps (a)-(c).

Abstract: Disclosed is a lens driving apparatus. The lens driving apparatus includes a base, a yoke coupled to the base, having an upper surface formed with a hole, a closed side surface, and an opened bottom surface, a bobbin movably installed in an inner portion of the yoke, a lens module coupled to the bobbin to go in and out the hole according to movement of the bobbin, a magnet fixed to an inner portion of the yoke, a coil fixed to an outer portion of the bobbin while facing the magnets, and springs coupled to the bobbin to provide restoration force to the bobbin.

Abstract: An optical assembly includes a first transparent substrate having first and second surfaces, a second transparent substrate having substantially parallel third and fourth surfaces, a reflective portion on the second transparent substrate, a plurality of filters between the first substrate and the reflective portion, the plurality of filters filtering light beams incident thereon, the plurality of filters and the reflective portion forming a bounce cavity within the second transparent substrate, a collimating lens for collimating light beams to be input to the bounce cavity, a tilt mechanism for introducing tilt to light beams input to the bounce cavity; an input port receiving light beams and an output port transmitting light beams. The tilt mechanism may be between the first and second substrate.

Abstract: A projection optical system for projecting an image of an image display element, includes a lens, a stop, and a holder configured to hold the lens and the stop and disposed at an image-display-element side of the stop. In addition, a light blocking member is disposed at the image-display-element side of the stop and fixed within the holder. At least a part of the light blocking member extends to a position nearer to an optical axis of the lens than the holder, and a face of the light-blocking member nearer to the image-display-element side is inclined in a section including an optical axis of the lens so that a point nearer to the optical axis comes closer to the image display element.

Abstract: A leaf spring supports a pillar shaped movable portion disposed in a center portion with respect to a cylindrical fixed portion disposed around the movable portion in the direction of a center axis shiftably so as to position the movable portion in a radial direction. The leaf spring is made of stainless steel having relative magnetic permeability which is not less than 1.1.

Abstract: Embodiments include optic mounts that may be adjustably positioned with a piezoelectric inertia driver. Position data feedback may be provided to embodiments of a piezoelectric inertia driver controller from an encoder, such as an optical encoder.

Abstract: A method of manufacturing suspension devices comprising the steps of: a) forming an integral elastic sheet, the elastic sheet having first and second suspension devices, each suspension device being provided with attachment parts configured to be fixed to a movable object, fixing parts configured to be fixed to a base, and elastic parts connected between the attachment parts and the fixing parts respectively and configured to bias the object relative to the base, the elastic parts of the suspension devices being alternately distributed; b) separating the first and second suspension devices from each other before being attached to the object.

Abstract: Provided are a lens barrel part and a method of producing the same, such that the generation of grinding debris due to friction with lenses is suppressed while maintaining the air permeability of porous ceramics. Those areas of a lens barrel part 1 which are in contact with the lenses are ground in the water by a polishing tool 25, with the result that in those regions of surfaces in contact with the lenses where fine projections exist, protection film portions 28 consisting of hydrates or oxides are created due to the generation of tribochemical reactions, and that in those regions of surfaces in contact with the lenses which are other than the regions where fine projections are present, there exist porous portions 29 where no tribochemical reaction occurs and where a porous state remains.

Abstract: A holding arrangement for an optical element, in particular for a cylindrical lens, includes a basic structure surrounding an optical element and a mounting device by which the optical element is supported on the basic structure. The mounting device has two degrees of freedom so that the optical element can be supported by the mounting device in a manner that allows the optical element to rotate about both about an optical axis and an axis perpendicular to the optical axis. If the optical element is a cylindrical lens, the axis perpendicular to the optical axis can be an axis perpendicular to an axial direction of the cylindrical lens. The disclosure further relates to a manipulator unit for an optical system which includes a holding arrangement.

Abstract: A lens module includes a lens barrel, a first lens, a second lens, a third lens, and two spacers. The lens barrel includes an object-side end and an image-side end. The first, second, and third lenses are received in the lens barrel and arranged in that order from the object-side to the image-side. One of the two spacers is positioned between the first lens and the second lens, and the other of the two spacers is positioned between the second lens and the third lens. Each of the spacers is chamfered to prevent the ingress of unwanted light.

Abstract: In a lens driving device, a rack gear portion is used as a gear portion so that the gear portion can be disengaged from the terminal end of the lead screw in the radial direction. To efficiently utilize a guide shaft formed with high precision, the guide shaft extends through a spring supporting frame of a lens holder that holds a lens, a movable member having the rack gear portion that meshes with the lead screw, whereby the movable member and the lens holder are linearly guided along the guide shaft, and the guide shaft also serves as the rotation axis of the movable member. A compression coil spring is wound around the guide shaft, and the rack gear portion is pressed against the lead screw by using the compression coil spring.

Abstract: A device for measuring eccentricity of a lens includes a support portion, an eccentricity detector, a driving device, a vacuum absorption device, a clamping device, and a rotatable pole. The support portion includes a plurality of gear teeth and a first through hole. The eccentricity detector is positioned above the lens. The driving device includes a driving mechanism and a motor. The motor rotates the driving mechanism. The vacuum absorption device includes an air pipe and a vacuum generation element. The vacuum generation element is for removing air from the air pipe. The clamping device includes a first clamping element and a second clamping element. The first clamping element cooperates with the second clamping element to locate and fix the lens. The rotatable pole includes a second through hole. The rotatable pole is for supporting the support portion.

Abstract: A lens driving device includes a ring-shaped driving coil fixed to a lens holder so as to position around a tubular portion thereof and a rectangular hollow cylindrical yoke including a plurality of flat-shaped permanent magnets opposite to the driving coil. Each flat-shaped permanent magnet has both ends in a horizontal direction which extend in the proximity of opposed two sides of the yoke. The driving coil is disposed so as to extend up to the vicinity of the both ends in the horizontal direction of each flat-shaped permanent magnet.

Abstract: An optical element holding apparatus includes an annular vibration attenuation plate, which covers a peripheral portion of a lens, and a connection member, which is formed of a damping alloy and which fixes the vibration attenuation plate to a frame body in a state of non-contact with the surface of the lens. The vibration attenuation plate and nitrogen gas in a clearance between the vibration attenuation plate and the surface of the lens form a squeeze film damper.

Abstract: A spring plate includes a plate body having a through hole defined at the center thereof, and a terminal perpendicularly extending from the plate body. The plate body includes an outer closed-loop frame, an inner closed-loop frame, and spring parts interconnected between the outer closed-loop frame and the inner closed-loop frame. The terminal has an end portion distal from the plate body with at least one of a through hole and a recess therein.

Abstract: A lens module includes a barrel, a first lens, a second lens, and a spacer. The first lens and the second lens are received in the barrel from an object side to an image side of the lens module. Each lens includes an optical portion and a non-optical portion around the optical portion. The spacer is positioned between the non-optical portion of the first lens and the non-optical portion of the second lens. The second lens includes an image-side surface. The non-optical portion on the image-side surface includes a contact portion. The contact portion defines a triangular notch.