Abstract: The present invention relates to a lens or objective for a camera, more particularly for a digital camera, comprising a housing, an actuating element arranged on the housing, and a lens element system that can be set into a plurality of settings, wherein the lens element system is embodied in such a way that in at least one setting an f-number is F?3. The lens element system is furthermore embodied in such a way that an actuation of the actuating element brings about a movement of two optical elements relative to one another, such that an intersection length difference of the lens element system can be set.

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: Systems are provided for positioning passive reflectors, such a lens/mirror assemblies, and other types of reflectors that need to be pointed in a particular direction. The systems can effectuate control of both the elevation and azimuth angles of the reflector. The systems can be configured so that a mount can rotate so as to vary the azimuth angle of the reflector by 360° or more without a need to reverse the direction of rotation of the reflector, and without the use of slip rings, RF rotary joints, or electrical cable wraps.

Abstract: The present invention discloses a manufacturing method of a condensing lens for a high concentration photovoltaic (HCPV) module. A buffer layer made of silicone is added between a glass and the condensing lens for adhering the glass to the condensing lens. Because the buffer layer can be formed on the glass before adhering to the condensing lens, a higher temperature for increasing adhesion between the glass and the buffer layer can be applied. It also allows the follow-up processes to have sufficient treatment time, thereby increasing the flexibility of processing schedule.

Abstract: An image forming lens includes a lens element having a flange part that is integral with the lens element. When assembled with an image pickup element to form an image pickup module, an outside perimeter portion of the lens element having a flange part, at a region nearest an image pickup element, is inclined so that outer diameters thereof increase when successively measured at positions nearer to the image pickup element. A frame of the image forming lens according to the invention has an inclined portion on the object side with an outer diameter that becomes smaller when successively measured nearer the object side. Satisfying one or more conditions insures accuracy in assembly and that there will be sufficient room near the object side outside the inclined portion to mount a light source, such as an LED, without having to increase the maximum outer diameter of the image pickup module.

Abstract: A lens displacement device includes a flexible piece, a fixed element and a mobile element. The flexible piece has a support, a flexible part and an oscillation absorber. The flexible part connects to the support and at least one gap exists between the flexible part and the support. The oscillation absorber is installed in the gap between the flexible part and the support. Moreover, the fixed element couples to the support of the flexible piece, and the mobile element couples to the flexible part of the flexible piece. Furthermore, the flexible part of the flexible piece is deformed in shape for providing a restoration force with the mobile element. A manufacturing process of the flexible piece is also disclosed.

Abstract: Some embodiments disclosed herein relate to a lens component having one or more lenses attached to a retainer portion configured to removably attach to communication devices such as mobile phones, tablet computers, media players, and the like. The retainer portion may be configured so as not to interfere with a user's view of a display panel of the communication device. In some embodiments, a plurality of lenses may be provided, and the lenses may be removably attached to the retainer portion and may be interchangeable. A structure for providing a flash may also be provided. In some embodiments, additional features may be provided, such as attachment components to facilitate attachment to stability devices, such as tripods, and to user-wearable accessories.

Abstract: A system for aligning a plurality of high-precision lenses in a lens train. Each of the lenses has at least two alignment tabs disposed around the perimeter of the lens. The lenses are aligned by placing the lenses in a jig having a plurality of high-precision alignment blocks. The lenses are attached to a lower-precision shroud, having slots that receive the alignment tabs. A gap-filling adhesive is used to provide a high-precision fit for the lenses in the shroud.

Abstract: A camera module includes a base board and a lens holder mounted on the base board. The lens holder includes a main body and at least one ventilation portion integrally formed with the main body. The main body includes a top wall and a peripheral wall extending from a peripheral edge of the top wall. The top wall and the peripheral wall cooperatively define an accommodating space. The top wall defines a viewing aperture through the top wall thereof and at least one riser vent positioned adjacent to the peripheral wall. The at least one ventilation portion covers the riser vent, and is made of a waterproof breathable material.

Abstract: A focusing device for a beam projector which includes a casing; a lens holder having at least one lens which is movable forward or backward in the direction of the optical axis; a movable member located at a side of the lens holder to be movable parallel to the direction of the optical axis together with the lens holder; and a control knob located adjacent to the lens holder and rotatably coupled on the casing.

Abstract: A method for manufacturing a lens unit including the steps of: forming a first lens array, having plural first lens sections and first reference surfaces formed in a predetermined arrangement, via glass forming by arranging a glass material between a first assembled molds and by clamping the molds; forming a second lens array, having plural second lens sections and second reference surfaces formed in a predetermined arrangement, via glass forming by arranging a glass material between a second assembled molds and by clamping the molds; forming a third lens array by stacking and bonding the first and second lens arrays so that an optical axis of each lens section of the first and second lens arrays coincide, by using the first and second reference surfaces; and cutting the third lens array into each lens unit which includes at least each one of the first and the second lens sections.

Abstract: A holder for at least one eyepiece is described. The holder includes an upper plate having at least two upper apertures therethrough, a top surface, and a bottom surface, and a lower plate having at least two lower apertures therethrough, a top surface, and a bottom surface. Each lower aperture corresponds to one of the upper apertures of the upper plate. When the upper and lower plates are mutually aligned, the at least one eyepiece may be inserted through corresponding upper and lower apertures. Furthermore, when one of the plates is selectively slid with respect to the other plate, the upper and lower apertures become misaligned to bind the at least one eyepiece to retain the eyepiece in the holder.

Abstract: A lens module includes a lens barrel, a first lens, an opaque plate, and a second lens. The first lens includes an imaging portion and a non-imaging portion surrounding the imaging portion. The non-imaging portion defines an annular conic surface. The opaque plate is annular conic shaped and contacts with the annular conic surface. The second lens includes an imaging portion and a non-imaging portion surrounding the imaging portion. The object-side surface of the non-imaging portion of the second lens is step-like shaped and includes at least two step surfaces. A junction of two adjacent step surfaces abuts against the opaque plate.

Abstract: A lens barrel includes a first frame configured to hold a first optical element, be movable in an optical-axis direction, and hold a position of the optical element in the optical-axis direction in a nonenergized state; a second frame configured to hold a second optical element, be movable in the optical-axis direction, and not hold a position of the optical element in the optical-axis direction in the nonenergized state; and a shock-absorbing portion provided at least one of the first and second frames. In the nonenergized state, the first frame is positioned within a range of the second frame.

Abstract: The present invention provides thermal compensation for a lens assembly comprising a polymer lens body. Polymers do have different thermal expansion coefficients which makes it necessary to compensate for thermal expansions to keep optical characteristics of such lenses within specifications when used under different environmental conditions. Also, it is necessary to provide thermal compensation during manufacturing of such lenses due to high temperatures during manufacturing steps.

Abstract: A membrane and lens assembly includes a flexible membrane mounted with a supporting structure, such as a plurality of spacers, a frame, a ring, a plate or a surface plate. At least one first lens mounts with a first side of the membrane. At least one actuator varies a characteristic of the membrane, such as membrane shape, position or tautness, to reposition the lens. In a related method of lens replication, a flexible membrane is attached to a ring and stretched with the ring. Lenses are replicated on one or both sides of the stretched membrane.

Abstract: A lens including: a lens body having first and second surfaces; a flange part formed to protrude from a periphery of the lens body and to have a cylindrical outer circumferential surface; a lens installation surface formed at an outer edge part of the flange part; a recessed part formed as a part of the flange part such that a part of the cylindrical outer circumferential surface is recessed toward the optical axis; and a gate root part located at a central part of the recessed part. The gate root part has a flat surface which is in a same level with respect to the lens installation surface. The gate root part lies on an optical axis side with respect to a virtual curved surface formed by extending the cylindrical outer circumferential surface through the recessed part.

Abstract: The present invention relates to embodiments of: (1) a unitary holographic drive head assembly mounting structure; (2) an assembly comprising a unitary holographic drive head assembly mounting structure and a plurality of holographic drive head components and/or subassemblies; (3) a subassembly comprising a spatial light modulator, detector array, and a beam splitter; (4) a device comprising a spatial light modulator and a physical aperture positioned over or an imaged aperture projected onto the photoactive area of the spatial light modulator; (5) a system for optically aligning or pointing a laser in a holographic drive head assembly; (6) a light source subassembly comprising a laser, a fiber coupling lens; and an optical fiber having a fiber connector ready output end; and (7) a light source subsystem comprising a laser source, beam conditioning optics, fiber coupling optics for receiving the conditioned light beam, and a fiber optic connector for receiving the conditioned light beam from the fiber couplin

Abstract: The disclosure relates to a connecting arrangement for an optical device, such as in microlithography. The connecting arrangement includes a first body, a second body and a connecting device. The first body contacts the second body in a laminar manner in a contact region. The connecting device is connected to the second body and contacts the first body via at least one contact unit. The connecting device is configured to generate a predefinable contact force in the contact region between the first body and the second body. The contact unit includes a plurality of separate contact elements. Each contact element is connected to the second body via a spring unit which can be elastically deformed to generate a contribution to the contact force.

Abstract: An adjustment mechanism for an optical system is provided. Two concentric eccentric rings support a back end of an optical element. The movements of the two rings relative to each other re-position the back end to affect the orientation of the field of view of the optical element. A clamp ring is provided to fix the position of the back end after the adjustment is completed.

Abstract: Disclosed are an optical element assembly comprising a base member in which occurrence of cracks in the base member upon cutting can be prevented and a method of manufacturing an optical unit. The optical element assembly comprises a base member and a plurality of lens members, wherein at least the base member of the optical element assembly is composed of an acryl resin having an alicyclic structure which is a polymer of a monomer represented by the following formula (1) in which linkage groups R2 and R3 lie between an atomic group A and R1OCO and between an atomic group A and OCOCR2, respectively.

Abstract: A lens mounting assembly includes a lens barrel with a first lens assembly. A lens mount includes an image sensor, and the lens barrel matingly connects with the lens mount in a manner which allows the first lens assembly to be moved along an optical axis to adjust a focus on the image sensor. A second lens assembly is provided for adjusting the focus on the image sensor during use of the lens. An alignment projection is provided on at least one of the first or second lens assemblies, the alignment projection being adapted to mate with a portion of the other of the first or second lens assemblies in order to directly optically align the first and second lens assemblies with the image sensor.

Abstract: A method of producing an optical element, in which a first and a second die are cooperated with each other so as to press-mold a material in order to produce an optical element including a lens portion, the first die has a circular cross-sectional shape, and the second die defines therein an interior space having a polygonal cross-sectional shape with respect to the direction of die-fastening, the first die is adapted to enter into the interior space of the second die in the direction of die-fastening in the interior space so to press-mold the material in order to form the lens surface while the material is bulged out through gaps between the first die and the second die around the lens surface whereby forming protrusions. An optical element and a mold assembly for an optical element are also provided.

Abstract: A lens unit and a lens driving apparatus are provided. First to third guide members have first to third axis lines, and the first to third axis lines are arranged in parallel with each other. A first lens holder has a first lens held by a first lens holding portion with a first main sliding portion guided by sliding on the first guide member, and a first sub sliding portion guided by sliding on the third guide member. A second lens holder has a second lens held coaxially with the first lens by a second lens holding portion with a second main sliding portion guided by sliding on the second guide member, and a second sub sliding portion guided by the third guide member.

Abstract: A lens unit composed of different materials includes a base and a lens. A part of a camera module of a different material from the lens is used as the base. The lens of optical resin is directly replicated on the base such that the lens is integrally formed on the base. A camera module is provided with the lens unit. The lens/lenses is/are formed on the single base/multiple bases to form the lens unit/units, using a die whose surface contacting the base slopes in relation to its central axis to allow the base to self-align.

Abstract: The invention features a label having a plurality of layers (e.g., at least two or more layers), in which at least one of the layers includes a thin film magnifier. Also featured are compositions to which the multi-layered label is affixed, methods of affixing the multi-layered label to compositions, and methods of making the multi-layered labels.

Abstract: An auxiliary device for measuring the coaxiality of a lens. The auxiliary device includes a cylindrical main body having a first surface and a flat second surface facing away the first surface, and a protrusion formed on the first surface and defining a reference convex surface. The second surface of the main body defines a position part. The position part is coaxial with the reference convex surface and configured to engage with the lens to measure the coaxiality of the lens.

Abstract: In a method for fabricating an integrated optical device by creating a wafer stack by stacking at least a top wafer carrying as functional elements a plurality of lenses on at least one further wafer including further functional elements, and separating the wafer stack into a plurality of integrated optical devices, wherein corresponding functional elements of the top and further wafer are aligned with each other and define a plurality of main optical axes, a method for providing a sunshade plate as part of an integrated optical device (10), including the steps of: providing a sunshade plate having a plurality of through holes, the through holes being arranged to correspond to the arrangement of the functional elements on the top wafer; and stacking the sunshade plate on the top wafer, with the through holes being aligned with said main optical axes.

Abstract: An auto-focus lens module includes a lens holder, a movable member, and a focusing spring assembly. The lens holder includes an immovable member and an upper plate. The upper plate has a surface facing the immovable member. First recesses are defined in the first surface. The movable member is received in the immovable member, and includes a lens barrel and ring. The lens barrel has a top surface. The ring is protruded from the top surface of the lens barrel. Arc portions equidistantly extend upward from the ring and are received in the recesses correspondingly. The focusing spring assembly contacts the immovable member and confines the movable member in the immovable member.

Abstract: A voice coil motor includes a movable member, a base, and a first elastic member. The movable member comprises a barrel, and a plurality of fixing posts protrudes from the bottom of the barrel. The base defines a through hole, a plurality of recessed portions, and a plurality of concavities. The axis of through hole is coaxial with the barrel. The recessed portions surround the aperture. Each of the recessed portions is arranged between two concavities. The depth of the recessed portion is less than the height of the fixing post, and the depth of the concavity is larger than that of the recessed portion. The elastic member comprises an elastic portion, which defines a first fixing hole. The fixing post extends through the first fixing hole and is received in the recessed portion.

Abstract: A lens fixing device includes a lens holder having a lens (lens area) made of a resin, and a mounting portion. The lens holder has two projections. Each of the two projections is formed with a guide surface and a mounted surface. A line of intersection of an extension of the guide surface of the projections and an extension of the mounted surface of the projections in a plane direction is aligned with an optical axis of the lens area. The lens holder is positioned with respect to a plane direction orthogonal to the optical axis by contact of the guide surfaces with receiving surfaces of the mounting portion. The lens holder is fixedly attached by an adhesive.

Abstract: An optical device includes a first optical component and a second optical component that are adjacent to each other in a direction of an optical axis. The optical device further includes a holding member that is formed with a resin material absorbing laser beams and that holds the first optical component via an elastic property of the resin material. The second optical component is formed with a resin material that allows the laser beams to pass and that is compatible with the resin material forming the holding member, and is fixed to the holding member by laser welding.

Abstract: A large optics stand provides a risk free means of safely tilting large optics with ease and a method of safely tilting large optics with ease. The optics are supported in the horizontal position by pads. In the vertical plane the optics are supported by saddles that evenly distribute the optics weight over a large area.

Abstract: A lens module includes a lens body; a lens holding member that movably holds the lens body along an optical axis of the lens body without tilting the optical axis; a displacement element that has a flat-plate shape of which one end edge on a side of the lens body along the optical axis is disposed as a free end and the free end is displaced to freely approach the lens body by applying a voltage; and a push-up member that is disposed on the free end of the displacement element and is inserted on one end surface side of the lens body, which is perpendicular to the optical axis, by the approach towards the lens body of the displacement element so as to push up the lens body in the optical axis direction.

Abstract: A lens actuator module includes a lens assembly with an optical centerline and a clear aperture, a bearing guide integrated adjacent to the clear aperture with the centerline of motion substantially parallel to the optical centerline, a linear actuator with a preloaded frictional contact point that moves the lens along the centerline. The preload force is perpendicular to the optical centerline, constant and generated in-line with the contact point such that the preload force produces substantially zero additional friction in the bearing guide irrespective of the location along the optical centerline.

Abstract: A deforming mechanism for deforming a transmissive optical element comprises a rotation member configured to hold the optical element and to rotate around an axis parallel to a tangential line of a circumference of the optical element at a portion where the rotation member holds the optical element, so as to deform the optical element by the rotation, a torque generating unit configured to generate a torque to rotate the rotation member around the axis, a holding base, and an elastic member connecting the holding base to the torque generating unit.

Abstract: A system and method for stabilizing an eye includes a contact element that is placed in contact with the anterior surface of the eye. The purpose here is to oppose movements of the eye during an ophthalmic surgical procedure. Importantly, while it is in contact with the eye, the contact element is positioned to exert minimal pressure on the eye. This is done to avoid causing any deformations of the eye that might otherwise adversely compromise a laser beam during the ophthalmic surgery.

Abstract: Provided are a wafer lens and a wafer lens manufacturing method which makes it possible to favorably manage lens inspection information. The wafer lens is formed by laying a diaphragm and an ID recording section on a glass substrate and covering the diaphragm and the ID recording section with a resin layer which forms optical members, the ID recording section having individual identification information (a wafer ID) of the wafer lens recorded therein. Further, the wafer lens manufacturing method comprises: an inspection step of inspecting optical components structured in the wafer lens; an identification information reading step of reading the wafer ID from the ID recording section; and a storage step of storing, in a management server, inspection information obtained in the inspection step while associating the inspection information with the wafer ID of the inspected wafer lens and further with component IDs thereof.

Abstract: An exemplary piezoelectric actuator includes a fixed barrel, a movable barrel in the fixed barrel, a piezoelectric driving module, a flexible circuit board on the fixed barrel, a bracing sheet, and a preloading module. The movable barrel receives a lens module. The driving module drives the movable barrel to move relative to the fixed barrel along an optical axis of the lens module. The driving module includes a piezoelectric member on the fixed barrel, and a friction member on the movable barrel and opposite to the friction member. The flexible circuit board is electrically connected with the piezoelectric member. The sheet is attached around the flexible circuit board. The preloading module is between the fixed barrel and the movable barrel. The preloading module is opposite to the piezoelectric driving module for exerting a pressure on the movable barrel, thereby making the friction member resist against the piezoelectric member.

Abstract: A lens module includes a barrel, a holder, and a ring-shaped elastic member. The barrel includes a connecting portion and a resisting portion, the connecting portion includes a first screw thread. The holder includes a second screw thread engaged with the first screw thread. The ring-shaped elastic member is compressed between the resisting portion of the barrel and the holder. The elastic member includes a number of first segments and a number of second segments, the first segments and the second segments are arranged in an alternate fashion and connected to each other, at least one of the first segments and the second segments is V-shaped.

Abstract: A lens includes a central optically active part, and a peripheral optically inactive part surrounding the optically active part. The optically inactive part includes a first surface, an opposite second surface, and a side surface connected between the first surface and the second surface. The side surface includes a first support area, a glue guide area, and a second support area in the order written. The glue guide area has a first groove defined therein. The first groove extends from a first side of the glue guide area adjacent to the first support area to an opposite second side of the glue guide area next to the second support area.

Abstract: An optical component is provided. The optical component includes an optical-path portion including an arm-connecting portion and a lower portion, a first arm extending from a first end of the arm-connecting portion, and a second arm extending from a second end of the arm-connecting portion. The first arm has at least one resting feature and the second arm has at least one resting feature. The optical-path portion has an input surface. When the resting features of the first arm and the second arm are positioned on a top surface at short edges of a trench in a trench system, the optical-path portion is vertically aligned in the trench.

Abstract: A lens device includes a lens assembly, a lens barrel receiving the lens assembly therein and a barrel holder. The lens barrel includes a first end, an opposite second end, a first flange extending outwards from the first end, and a second flange extending outwards from the second end. The barrel holder is located between the first flange and the second flange. The barrel holder includes a first part, a second part, and two pairs of magnetic units each including a first magnetic element fixed to one of the first part and the second part, and a second magnetic element fixed to the other of the first part and the second part, the second magnetic element magnetically attracted to the first magnetic element. The first part is securely attached to the second part by magnetic attraction between the first and second magnetic elements.

Abstract: A lens module includes a lens barrel, a lens and an aperture plate. The lens barrel includes a main body. The lens barrel includes a main body with an inner sidewall. The lens is received in the main body and includes an optical portion and a non-optical portion surrounded the optical portion. The aperture plate is disposed on the image-side surface of the non-optical portion of lens. The aperture plate defines a plurality of cutouts on the outer periphery thereof and thereby leaving a plurality of flanges at the outer periphery thereof. The flanges abut the inner side wall. The cutouts are coated adhesive to firmly attach the aperture plate on the image-side surface of the lens and fixed on the inner sidewall of the main body.

Abstract: An adaptive mounting for an image capture device includes a lens holder, a tilt bracket rotatably engaging with the lens holder, and a pan bracket pivotally connecting the tilt bracket via a pair of adjustment screws. The lens holder includes two opposite connecting portions used for engaging with either a vari-focus lens module or a fixed focus lens module.

Abstract: A lenses assembly includes a first lens, a second lens, and adhesive material. The first lens includes two axially extending protrusions. The second lens includes two radially extending protrusions. The second lens engages with the first lens by engagement between the axially extending protrusions and radially extending protrusions. The axially extending protrusions and radially extending protrusions are alternately arranged around a circumferential direction of the first lens. The adhesive material is filled into gaps between the engaged protrusions to fixedly interconnect the first lens and the second lens.

Abstract: A sliding cover structure and an electronic apparatus are disclosed. The sliding cover structure is used for covering a lens, and includes a base, a first cover, a second cover and a swing part. The first cover slides forwards and backwards on the base, and slides between an opening position that does not cover the lens and a closing position that covers the lens. The second cover moves upwards and downwards on the base. The swing part is pivoted with the base and has a first contact end and a second contact end. The pivoting position of the swing part and the base is located between the first contact end and the second contact end so that the swing part can perform a seesaw operation. The first contact end is located below the second cover so that the first contact end drives the second cover to move upwards.

Abstract: An optical assembly has a lens element having a plurality of radially extending tabs and a mounting structure having a plurality of retaining members. The retaining members extend in a direction substantially parallel to an optical axis defined by the mounting structure and are positioned complementary to the radially extending tabs of the lens element. A portion of the mounting structure is in an interference fit with the a portion of the lens element.

Abstract: A first lens having a first bottom surface and a first top surface at opposite sides thereof; and a first supporter having a first supporting surface and a second supporting surface at opposite sides thereof, the first supporting surface being flat, the second supporting surface being in contact with the first bottom surface, the first supporter being made of transparent material, and a refraction index of the first supporter being different from a refraction index of the first lens. A lens assembly array and method of making the lens assembly array are also provided.

Abstract: A lens assembly is provided. The lens assembly comprises a lens and a bearing seat. The bearing seat has a bearing surface for bearing the lens, while the bearing surface is adapted to adhere to the lens so that the lens is fixed on the bearing seat.