Abstract: A light emitting device package may be provided that includes: a substrate; a first light emitting chip disposed on the substrate; a plurality of second light emitting chips disposed on the outer circumference of the first light emitting chip; and a lens formed on the first and the second light emitting chips.

Abstract: An LED lamp includes: a plurality of light source units, each of which includes one or more LED chips and an emission surface through which light from the LED chips is emitted; and a lens unit having a plurality of lenses, each of which is located in front of the emission surface of each of the plurality of light source units.

Abstract: A system and method for reducing the M2 value of a single asymmetric laser emitter while maintaining the power output of the emitter. In some embodiments the brightness of the output of such a system is equivalent to a portioned section of the single laser emitter. A WBC step is performed along a portioned or non-portioned single laser emitter to reduce the M2 value.

Abstract: The invention relates to mechanical construction of the optics for a pencil optical input peripheral device for fast and comfortable computer control. The input light reflecting element and at least one convex or aspherical lens is fitted above the input opening aslant to the axis of the longitudinal pencil body in the angled tube. There is a scan sensor fitted behind the output opening of the angled tube. There is also the light source beside the input opening of the angled tube in the recessed opening of the longitudinal pencil body. Axes of the light source and the input opening of the angled tube are at an acute angle. The output light reflecting element can be fitted before the scan sensor aslant to the axis of the longitudinal pencil body in the angled tube and the light permeable cover can be fitted before the input opening of the angled tube and/or behind the light source. The input light reflecting element and/or the output light reflecting element consist of plane mirrors or light reflecting prisms.

Abstract: The present invention concerns a method of manufacturing a lens for motor vehicle lighting modules, the method being intended to generate on the output surface (104) of said lens (100) microstructures formed by level differences situated on said output surface (104), the method including the following steps of forming a meshing on the output surface of said lens such that each mesh has similar dimensions, and generating in each mesh a microstructure formed by an output surface level difference, each level difference having a profile that varies as a function of the position of the mesh on the output surface of the lens.

Abstract: The present invention relates to a sheet enabling to form dynamic three-dimensional images and a device for preparing thereof. The sheet comprises a base layer (1), a transparent protective layer (2), a reflective layer (3), and pixel points (4) that can form images. The transparent protective layer (2) is disposed at one side of the base layer (1), the pixel points (4) are embedded in the transparent protective layer (2). The pixel points (4) consist of microlenses (401) tightly closed together. The reflective layer (3) is disposed downbently at a lower part of the microlenses (401), wherein picture-text is recorded in the reflective layer (3). There is an altitude difference H between horizontal positions of two adjacent pixel points (4). Microlenses (401) in any one of pixel point have the same curvature radius, and curvature radius of microlenses (401) in two adjacent pixel points (4) have a difference of 1 to 70 ?m.

Abstract: A stereoscopic image display device includes: an image display unit that can display parallax images; an optical component that causes the parallax images to be recognized as a stereoscopic image; and a back light unit that is arranged on a rear face side of the image display unit, wherein the back light unit includes a first illumination section that illuminates the image display unit at a first outgoing angle at the time of displaying a planar image by using the image display unit and a second illumination section that illuminates the image display unit at a second outgoing angle, which is narrower than the first outgoing angle, at the time of displaying a stereoscopic image by using the image display unit and the optical component.

Abstract: An optical device for providing a synthetic integral image (25) comprises a polymer foil stack. A first interface of the polymer foil stack comprises optically distinguishable image data bearer structures (16A-C) in a first array. A second interface of the polymer foil stack has focusing elements (1) in a second array. A ratio between distances between neighboring objects in the first array and of focusing elements in the second array in a first direction is different from a ratio between distances between neighboring objects in the first array and of focusing elements in second array in a second direction. This leads to that the synthetic integral image corresponding to the image data bearer structures is perceptible with requested proportions when the polymer foil stack is given a certain curvature. Also polymer foil stacks giving rise to synthetic integral image only when viewed from a very short distance are described.

Abstract: A rod lens array is configured so that when a relation between R and r0 is set to be R?r0?0.8R, and the gradient index of the rod lens is approximate to n(r)2=n02{1?(g·r)2}, an overlap degree m, defined by m=X0/2R, is 2.55 or more and 4 or less and an aperture angle of the rod lens, represented by n0·g·r0, is 0.1 or more and less than 0.22. The array is capable of minimizing light quantity unevenness even where there may be assembly error or aged deterioration occurs. An equal-magnification imaging optical apparatus usefully includes a rod lens array.

Abstract: An elementary image acquisition or display device, including a focusing structure with microlenses, each microlens being shaped to focus incident light beams towards a substrate while avoiding intermediate conductive tracks and vias.

Abstract: A manufacturing method of microstructure comprises steps of: a motion determination step which determines the motion of a substrate relative to at least a photomask; a microlens determination step which determines the profile of a microlens unit on the substrate; an analysis step which calculates the feature of the photomask according to the motion of the substrate and the profile of the microlens unit by using a numerical analysis method; a production step which produces the photomask according to the feature of the photomask; driving the substrate to do the motion determined in the motion determination step, and meanwhile making a laser light illuminate the substrate through the photomask to manufacture the microlens unit on the substrate by the superposition effect of the laser light; and performing a photolithography process by using the microlens unit to produce a microstructure on a photoresist substrate.

Abstract: A rod lens and methods for producing such a rod lens are disclosed. The rod lens and methods include a sealing glass and holder glass or a metallic holder that are heated so that only the sealing glass melts and forms a spherical cap to define a lens element joined to a light guiding element. A plurality of rod lenses may form an array arrangement.

Abstract: A finder optical system 20 includes a focusing glass 21 including a collection surface 21a that collects a light beam and a diffusion surface 21b that diffuses the collected light beam, an eyepiece 23 that receives a part of the diffused light beam, a photometry lens 24 arranged near the eyepiece 23, and a photometry sensor 25 on which an image of another part of the light beam diffused by the diffusion surface 21b is formed via the photometry lens 24, a plurality of micro lenses are arranged on the diffusion surface 21b of the focusing glass 21, at least one micro lens of the plurality of micro lenses has at least two radii of curvature on its cross section in a predetermined direction, and the at least one micro lens satisfies R1<R2 where R1 and R2 are radii of curvature in first and second areas, respectively.

Abstract: A first lens array unit includes a first lens array plate and a second lens array plate in which a plurality of lenses are provided in the main scanning direction, and a first light shielding member piece and a second light shielding member piece provided with a plurality of through holes corresponding to the lenses. The first lens array plate, the second lens array plate, the first light shielding member piece, and the second light shielding member piece are formed as one piece. The lens array is built by bending joints joining the lens array plates and the light shielding member pieces such that the lens is located to directly face the corresponding through hole.

Abstract: A moire magnification device is disclosed, including a transparent substrate carrying: a regular array of micro-focusing elements on a first surface, the focusing elements defining a focal plane; and a corresponding first array of microimage elements located in a plane substantially coincident with the focal plane of the focusing elements. The pitches of the micro-focusing elements and the array of microimage elements and their relative locations are such that the array of micro-focusing elements cooperates with the array of microimage elements to generate magnified version of the microimage elements due to the moire effect. Along at least one axis across at least a first region of the device, the pitch between the microimage elements and/or between the micro-focusing elements continuously varies across the respective array(s), whereby the moire effect causes different degrees of magnification of the image elements to occur.

Abstract: A solid-state imaging device according to an embodiment includes: an imaging element including an imaging area formed with a plurality of pixel blocks each including pixels; a first optical system forming an image of an object on an imaging surface; and a second optical system re-forming the image, which has been formed on the imaging surface, on the pixel blocks corresponding to microlenses, the second optical system including a microlens array formed with the microlenses provided in accordance with the pixel blocks. The microlenses are arranged in such a manner that an angle ? between a straight line connecting center points of adjacent microlenses and one of a row direction and a column direction in which the pixels are aligned is expressed as follows: ?>sin?1(2dp/Dml), where Dml represents microlens pitch, and dp represents pixel pitch.

Abstract: Multi-mode diode emitters are stacked in a staircase formation to provide a spatially-multiplexed output. Improved coupling efficiency is achieved by providing tilted collimated output beams that determine an effective step height of the stepped structure. Since the effective step height is dependent on the tilt angle, a variable number of emitters can be used inside packages having a same physical step height, while still attaining high coupling efficiency.

Abstract: According to one embodiment, an image display apparatus includes a light source array, a lens array, a transmission type display and a field lens. The light source array has a plurality of point light sources. The lens array is facing the light source array, and having a plurality of lenses, each of which corresponds to a first number of the point light sources. The transmission type display is facing the lens array and configured to display an image by light beams from the point light sources. The field lens is facing the transmission type display and configured to output light beams from the transmission type display in a first direction.

Abstract: An aspect of the invention provides a security device including an array of printed lenses arranged on a first surface of a substrate and a microimage array underlying the array of printed lenses, whereby a synthetic image of portions of the microimages is generated by the lenses. The security device further comprises at least one tactile element arranged on the first surface of the substrate which is of greater or lesser height than the printed lenses, the at least one tactile element being registered to the array of printed lenses.

Abstract: A silicon-based thermal energy transfer apparatus that aids dissipation of thermal energy from a heat-generating device, such as an edge-emitting laser diode, is provided. In one aspect, the apparatus comprises a silicon-based base portion having a first primary surface and a silicon-based support structure. The silicon-based support structure includes a mounting end and a distal end opposite the mounting end with the mounting end received by the base portion such that the support structure extends from the first primary surface of the base portion. The support structure includes a recess defined therein to receive the edge-emitting laser diode. The support structure further includes a slit connecting the distal end and the recess to expose at least a portion of a light-emitting edge of the edge-emitting laser diode when the edge-emitting laser diode is received in the support structure.

Abstract: A container (10) for consumer goods comprises a first panel (16) having a pattern (22) applied to an area (20) of the external surface thereof; and a second panel (26) comprising a transparent optical element. The first panel (16) and the second panel (26) are moveable relative to each other between a first position, in which the transparent optical element in the second panel (26) does not overlie the pattern (22) on the first panel (16), and a second position, in which the transparent optical element in the second panel (26) at least partially overlies the pattern (22) on the first panel (16), whereby an altered image of the pattern is visible through the transparent optical element.

Abstract: An optical element includes a first microlens array unit and a second microlens array unit in each of which a plurality of microlenses are arranged. The first and second microlens array units are arranged opposite to each other with a distance which is longer than a focal length of the microlenses arranged in the first microlens array unit. The first microlens unit is arranged on a light-incident side with respect to the second microlens array unit. The interval between the microlenses arranged in the second microlens array unit is narrower than the interval between the microlenses arranged in the first microlens array unit. The optical element can appropriately suppress the occurrence of excessive pixel bright spot.

Abstract: An optical receiver module includes: a lens array including a plurality of condenser lenses arranged in one direction to define a plane with optical axes in parallel to each other; and a light receiving element array including a plurality of light receiving elements each configured to receive light emitted from each of the condenser lenses. The light receiving element array includes: a semiconductor substrate to which the light from each of the condenser lenses is input and through which the light is transmitted; and light receiving portions each configured to receive the light transmitted through the semiconductor substrate and convert the light into an electrical signal. A shift of the optical axis of each of the condenser lenses from a center of each corresponding one of the light receiving portions is larger in a direction perpendicular to the one direction within the plane than in the one direction.

Abstract: A method and apparatus for laser beam splitting and shaping is disclosed wherein two beam splitters are used to split one input laser beam into four beams in a generally rectangular pattern. Half-wave plates are used to adjust the power of the input laser beam between the four laser beams. A variable power optical telescope comprising negative and positive lens pairs for the four laser beams is used to adjust the divergence of the four beams, and pointing control prism wedges are used to point or steer the four beams to be parallel to each other and to adjust their relative spacing to create a flat top profile.

Abstract: A method for fabricating a micro lens array is provided. The method includes forming a first lens material structure on a substrate. The first lens material structure includes a plurality of elevated portions. The elevated portions are separated by recesses. Moreover, the plurality of elevated portions have an average height of at least 3 micrometers. Furthermore, the method for fabricating a micro lens array includes depositing a dielectric material on the first lens material structure and the recesses to form a second lens material structure. The second lens material structure has an average thickness of at least 1 micrometer. Moreover, the first and second lens material structures form together the micro lens array.

Abstract: A microlens includes a lens center portion having a lens-curved surface and a lens circumference portion having a linear side surface. In the case where length of the side surface is taken as L1, length of an aperture is taken as Ax, an angle formed by a normal of the side surface and incident light on the microlens is taken as ?1, and an angle formed by the normal of the side surface and output light from the microlens is taken as ?2, a relational expression of Equation 1 is satisfied.

Abstract: Provided is a light-emitting element having high luminance and high directivity and emitting light in a controlled polarization state. The light-emitting element comprises substrate 3 and light emitting part 10 disposed on substrate 3 for emitting light in which light intensity of a polarization component in first direction x parallel to substrate 3 is higher than light intensities of polarization components in other directions. Light emitting part 10 includes active layer 12 for generating light and a plurality of structural bodies 14a disposed on a light-emitting side of light emitting part 10 with respect to active layer 12 and arrayed two-dimensionally along a surface substantially parallel to active layer 12. Each of structural bodies 14a has width w1 along first direction x and width w2 along second direction y perpendicular to first direction x, width w1 along first direction x and width w2 along second direction y being different from each other in a cross section parallel to active layer 12.

Abstract: A brightness enhancement film includes a substrate; and a microlens structure formed on the substrate, wherein the microlens structure comprises a plurality of microlenses, each of the microlenses comprising a bottom surface contacting with the substrate, the bottom surface of each of the plurality of microlenses being of a polygonal shape such that at the substrate each of the plurality of microlenses is in close contact with adjacent microlenses surrounding it, without gaps leaving between them. The present invention also discloses a backlight module and a display apparatus comprising the above brightness enhancement film. The brightness enhancement film can improve optical gain property, reduce the thickness of the display apparatus and expand the view angle.

Abstract: A wafer level lens includes a first lens structure of a first polymeric material coupled to a second lens structure of a second polymeric material, wherein an interface is formed by opposing surfaces of the first lens structure and the second lens structure, the opposing surfaces having no air gap therebetween, at least one aperture disposed between the first lens structure and the second lens structure, wherein the aperture contacts the first lens structure and the second lens structure and wherein a supporting substrate is not positioned between the first lens structure and the second lens structure, and a spacer coupled to and separate from the wafer level lens.

Abstract: A method for providing an optical element may include providing an optical feature in the optical element that spreads or distributes light passing through the optical element. The method may also include providing a texturing in at least a portion of the optical feature of the optical element.

Abstract: An optically variable device (“OVD”) with an integral image system that includes a focusing element and an array of micro-objects which, when viewed through the focusing element, changes in appearance depending on the relative location from which the OVD is observed. A security device including the OVD and methods for creating the OVD are also disclosed.

Abstract: An image capturing module includes an image sensing unit and an optical auxiliary unit. The image sensing unit includes a carrier substrate and an image sensing chip disposed on the carrier substrate and electrically connected to the carrier substrate. The optical auxiliary unit includes a housing frame for covering the image sensing chip and a movable lens assembly movably disposed in the housing frame. The movable lens assembly includes a movable casing movably disposed in the housing frame, at least one optical lens group disposed in the movable casing, a microlens array substrate disposed in the movable casing, and a nonconductive photosensitive film layer disposed on the microlens array substrate for increasing the light absorption capability.

Abstract: Disclosed herein are an obstacle sensing module and a cleaning robot including the same. The cleaning robot includes a body, a driver to drive the body, an obstacle sensing module to sense an obstacle present around the body, and a control unit to control the driver, based on sensed results of the obstacle sensing module. The obstacle sensing module includes at least one light emitter including a light source, and a wide-angle lens to refract or reflect light from the light source so as to diffuse the incident light in the form of planar light, and a light receiver including a reflection mirror to again reflect reflection light reflected by the obstacle so as to generate reflection light, an optical lens spaced from the reflection mirror by a predetermined distance, to allow the reflection light to pass through the optical lens, and an image sensor, and an image processing circuit.

Abstract: A visual display assembly adapted for use as an anti-counterfeiting device on paper currency, product labels, and other objects. The assembly includes a film of transparent material including a first surface including an array of lenses and a second surface opposite the first surface. The assembly also includes a printed image proximate to the second surface. The printed image includes pixels of frames of one or more images interlaced relative to two orthogonal axes. The lenses of the array are nested in a plurality of parallel rows, and adjacent ones of the lenses in columns of the array are aligned to be in a single one of the rows with no offset of lenses in adjacent columns/rows. The lenses may be round-based lenses or are square-based lenses, and the lenses may be provided at 200 lenses per inch (LPI) or a higher LPI in both directions.

Abstract: A CISM includes a lens array in which a plurality of lenses is arranged in a row form so that the optical axes are parallel to one another, and an incident optical image is formed from one end side in the optical axis direction of the lens array, thereby forming an image on the other end side. The CISM includes a light blocking member in which a plurality of through holes that allow light to pass through is provided in a row form in the arrangement direction. In the light blocking member, the inner wall surface of the through holes that intersects the arrangement direction includes reflection surfaces that intersect a sub-scanning direction. The reflection surfaces reflect light incident on the same reflection surface in a direction that intersects the arrangement direction.

Abstract: A diffuser stack may include a first film with a first index of refraction and a second film proximate the first film. The second film may have a second index of refraction that is higher than the first index of refraction. An interface between the first film and the second film may include an array of microlenses of substantially randomized sizes. The microlenses may include sections of features that are substantially spherical, polygonal, conical, etc. The first and second films may be disposed between an array of pixels and a substantially transparent substrate. An anti-reflective layer may be disposed between the first film and the second film.

Abstract: An object is to provide an image display sheet capable of realizing a smooth pseudo moving image and observing the image with reduced in discomfort. A configuration is provided in which a lenticular sheet composed of an arrangement of a plurality of cylindrical lenses 1a and an image forming layer 3 are laminated, and the image display sheet is formed capable of observing an image formed on the image forming layer 3 from the convex shape side of the cylindrical lenses 1a of the lenticular sheet, as a virtual image with movement, or movement and deformation. The image forming layer 3 is formed repeatedly with a plurality of images 3 for displaying virtual images in association with the cylindrical lenses 1a so as to correspond to the cylindrical lenses 1a, respectively, one-on-one, and difference between an arrangement pitch length A of the cylindrical lenses 1a and a pitch length B of the repeatedly formed images 3a formed on the image forming layer 3 is in a range of 0% to 10%.

Abstract: A lens array is provided in which the edges of concave-shaped lens faces can be formed with high accuracy and the accuracy of position measurement of the lens faces can be improved. Outer peripheral edge portions 7a of a plurality of lens faces 7 are formed in positions further towards face apex portion sides than a predetermined surface 2 with cylindrical stepped surfaces 12 for each lens face 7 therebetween, one end of the stepped surfaces 12 being the outer peripheral edge portions 7a and another end being a plurality of opening portions 2a formed on the predetermined surface 2 such as to respectively face the outer peripheral edge portions 7a.

Abstract: A silicon-based thermal energy transfer apparatus that aids dissipation of thermal energy from a heat-generating device, such as an edge-emitting laser diode, is provided. In one aspect, the apparatus comprises a base portion and a support portion. The base portion is made of silicon and includes a first primary surface. The first primary surface includes at least first and second V-notch grooves thereon. The support portion is made of silicon and includes at least first and second edges that are interlockingly received in the first and second V-notch grooves when the support portion is mounted on the base portion.

Abstract: An optical element array includes a first optical element and a second optical element that is further away from a center of an array region than the first optical element. Orthogonal projections of the first and second optical elements include first and second ends and third and fourth ends, respectively, and vertices thereof are at first and second positions. An interval between the third end and the second position is smaller than that between the first end and the first position and that between the fourth end and that second position. The first and second optical elements respectively include first and second outer edges extending from the vertices thereof to the second and fourth ends. A radius of curvature, or a median value of the radius of curvature, of the second outer edge is in the range of 80% to 120% of that of the first outer edge.

Abstract: An embodiment of a wide angle personal display projector is configured for positioning in relation to a user's eyeball, and includes a curved display layer. A curved micro lens array having a curvature generally matching the display curvature is positioned relative to the display layer so that the micro lens array is between the display layer and the user's eyeball. In another embodiment, a binocular personal display system includes a frame structure for supporting left and right personal display projectors in relation to the user's left and right eyeballs.

Abstract: A probe for use with an imaging system, including a scanning device configured to receive a first light beam from a light source, a beam-divider configured to split the first light beam into a plurality of second light beams, and a focusing device configured to focus each of the second light beams on respective locations in an object of interest.

Abstract: A device forms laser radiation which has partial beams interspaced in a first direction that is perpendicular to the direction of propagation of the laser radiation, especially for forming laser radiation which is emitted by a laser diode bar. The device contains a plurality of reflective surfaces on which at least one of the interspaced partial beams can be reflected in such a manner that the distances of the partial beams are smaller relative to each other after reflection than before reflection.

Abstract: There is provided a method of manufacturing a microlens array substrate with improved manufacturing yield and high quality, the method including: forming a groove part along an outer edge of a first area on a surface of a substrate; forming a mask layer to cover a side of the surface, forming a plurality of openings in the first area, and forming openings along the outer edge of the first area; performing isotropic etching on the substrate through the mask layer, forming a plurality of recesses in the first area, and forming recesses across a boundary part between the first area and the groove part; removing the mask layer from the substrate; forming a light transmission material layer that has a refractive index, which is different from a refractive index of the substrate, to cover the side of the surface of the substrate and to bury the plurality of recesses; and planarizing an upper surface of the light transmission material layer.

Abstract: A microlens array substrate includes a substrate having transparency and having a plurality of concave portions provided on a first surface to correspond to a plurality of pixels, and a lens layer having a different refractive index from a refractive index of the substrate, which is provided on the first surface of the substrate to fill in the plurality of concave portions, in which each of the plurality of concave portions has a flat portion arranged at the center portion, a curved surface portion arranged to surround the flat portion, an edge portion arranged to surround the curved surface portion and connected to the first surface of the substrate, and an angle between the edge portion and the first surface in a cross section passing through the center portion is smaller than an angle between a virtual curved surface obtained by extending the curved surface portion toward the first surface and the first surface.

Abstract: Disclosed herein are techniques for the reduction speckle of a projection display system using novel lenslet integrators and related methods. In one embodiment, a lenslet integrator system for reducing speckle on a display screen may comprise a first lenslet array configured to receive incoming light for use in displaying an image on a display screen. Specifically, the first lenslet array has motion sufficient to reduce speckle by averaging multiple speckle patterns across its array. Such an exemplary system may also include a second lenslet array configured to receive light that is roughly focused from the moving first lenslet array, due to the motion of the first array. In addition, such systems may also include an output lens configured to receive light focused from the second lenslet array for output from the system for illumination of the display screen.

Abstract: Optical apparatus includes a diode-laser bar stack having N fast-axis stacked diode-laser bars cooperative with a parallel sided transparent stacking plate. The stacking plate receives N original beams from the N diode-laser bars and converts the N beams to 2N fast-axis stacked beams having one-half of a width the original beams and one-half of a fast-axis spacing between the original beams.

Abstract: An optical mold including a spacer cavity portion, a lens cavity portion and a flow stop control portion for allowing optical lens material to flow between the spacer cavity portion and the lens cavity portion and an optical lens array formed therefrom. The optical mold may further include a pedestal located within the spacer cavity portion for supporting the mold during a puddle dispensing process. A method for using the optical mold including the spacer cavity portion, the lens cavity portion, and the flow cavity portion, and optionally the pedestal.

Abstract: According to an embodiment, a microlens array for a solid-state image sensing device includes a plurality of microlenses and a state detector. The plurality of microlenses are disposed in an imaging microlens area and is configured to form two-dimensional images. The state detector is disposed on a periphery of the imaging microlens area and is configured to, on an image forming surface of the microlenses, generate images having a smaller diameter than images formed by the microlenses.

Abstract: According to one embodiment, an imaging lens includes a first optical system and a microlens array. The first optical system includes an optical axis. The microlens array is provided between the first optical system and an imaging element. The microlens array includes microlens units provided in a first plane. The imaging element includes pixel groups. Each of the pixel groups includes pixels. The microlens units respectively overlap the pixel groups when projected onto the first plane. The first optical system includes an aperture stop, and first, second, and third lenses. The first lens is provided between the aperture stop and the microlens array, and has a positive refractive power. The second lens is provided between the first lens and the microlens array, and has a negative refractive power. The third lens is provided between the second lens and the microlens array, and has a positive refractive power.