Abstract: An optical projector comprises a collimated light source, a pattern generating optical element, and a variable optical element positioned optically between the collimated light source and the pattern generating optical element. The variable optical element is configured to adjust a divergence of a light beam incident on the pattern generating optical element. The pattern generating optical element is configured to emit patterned light when the variable optical element is in a first state, and to emit non-patterned light when the variable optical element is in a second state.

Abstract: A lens includes a lens body comprising a cylindrical surface along an optical axis direction and a fixed portion radially outwardly protruding from the lens body, comprising a diameter diminishing more and more from an image side toward a subject side along an optical axis of the lens body, and including an inclined surface contiguous to the cylindrical surface of the lens body.

Abstract: Trapezoidal protrusions, which protrude to the inside of a region, are provided on a right-side part and a left-side part of a mounting member. Holding sections, which extend in a circumferential direction, are formed in lateral surfaces of the trapezoidal protrusions. The holding sections include first holders which are opened to an upper side, and a second holder that is opened to a lower side. The first holders, and the second holder are respectively provided with second protrusions which protrude into a groove in a plural number, and can maintain the cable in a groove. First protrusions are respectively provided on rear-side ends to guide lead-out of the cable from the mounting member.

Abstract: An optical imaging system includes a first lens, a second lens, a third lens, a fourth lens having a negative refractive power, a fifth lens having a negative refractive power, a sixth lens, and a seventh lens having a positive refractive power. The first lens to seventh lens are sequentially disposed in a direction from an object side toward an imaging plane.

Abstract: A wafer level camera module includes an image sensor including an imaging region formed on a top surface thereof, a first support layer disposed on the image sensor and having an opening, and first and second zooming units sequentially stacked having a second support layer interposed therebetween. Each zooming unit includes a piezoelectric thin film disposed on the first support layer and having an opening. Each zooming unit further includes a deformable layer disposed on the piezoelectric thin film. Each zooming unit additionally includes a lens attached to the deformable layer and positioned to overlap the imaging region. The wafer level camera module additionally includes a first conductive via penetrating through the camera module to be electrically connected to the first piezoelectric thin film. The camera module further includes a second conductive via penetrating through the camera module to be electrically connected to the second piezoelectric thin film.

Abstract: An optical arrangement including an optical component with a basic body and at least one retaining element, which is designed as an integral element of the optical component or which is actively connected to the optical component is disclosed. The retaining element is affixed on a first contact position of the basic body and a carrier, on which the optical component is supported by means of the retaining element. The retaining element is affixed on a second contact position of the carrier and is arranged in such a manner that it can be pivoted between a first contact position and a second contact position. The arrangement is conducted in such a manner that during a thermal expansion of the basic body in the direction of the carrier and/or with a thermal expansion of the retaining element a movement of the first contact position along the optical axis is generated.

Abstract: A wearable display includes a first optical section, a main body, and a jig receiver. The first optical section emits light. The main body includes a second optical section that is connected to the first optical section and outwardly emits the light as image light, and a casing that supports the second optical section. The jig receiver includes a first guide that supports a first protrusion of a jig, a second guide that supports a second protrusion of the jig, and a third guide that supports a third protrusion of the jig. The jig receiver is provided in the casing such that at least two of the first, second, and third guides are spaced apart from each other in the first axis direction and at least two of the first, second, and third guides are spaced apart from each other in the third axis direction.

Abstract: An optical adapter includes a support, which can be removably coupled to an image acquisition device. The support has a substrate made of substantially transparent material. The substrate has a proximal surface intended for facing towards the device and a distal surface located at a distance from the proximal surface and intended for facing towards an object to be observed. The support also has a lens located in a seat obtained in the substrate and facing towards the objective of the device. In addition, the support has a reflector located laterally relative to the lens and arranged for facing towards a light source integrated into the device and conveying the light emitted by the light source in a transversal direction towards the lens and past the distal surface.

Abstract: An optical imaging system includes five lens elements, the five lens elements being, in order from an object side to an image side: a first lens element having positive refractive power; a second lens element having negative refractive power; a third lens element having positive refractive power; a fourth lens element having positive refractive power; and a fifth lens element having negative refractive power.

Abstract: An objective lens is used for DNA sequencing. An example system includes a flow cell, the objective lens, and a camera. Light from the flow cell is imaged by the camera through the objective lens. The objective lens can provide a long working distance; a flat field curvature; a high numerical aperture; and/or a wide field of view.

Abstract: An optical arrangement including an optical component with a basic body and at least one retaining element, which is designed as an integral element of the optical component or which is actively connected to the optical component is disclosed. The retaining element is affixed on a first contact position of the basic body and a carrier, on which the optical component is supported by means of the retaining element. The retaining element is affixed on a second contact position of the carrier and is arranged in such a manner that it can be pivoted between a first contact position and a second contact position. The arrangement is conducted in such a manner that during a thermal expansion of the basic body in the direction of the carrier and/or with a thermal expansion of the retaining element a movement of the first contact position along the optical axis is generated.

Abstract: A variable magnification optical system includes a plurality of lens element, and includes in order from an object side, a first lens unit having a positive refractive power, a second lens unit having a negative refractive power, a third lens unit having a positive refractive power, and at least one lens unit. An aperture stop is either positioned between the second lens unit and the third lens unit, or positioned in the third lens unit. At the time of zooming from a wide angle end to a telephoto end, the first lens unit is fixed, the second lens unit moves from the object side to an image-plane side, and at least one of lens units positioned on an image side of the aperture stop moves. The first lens unit includes at least four positive lens elements and at least two negative lens elements.

Abstract: It is provided that a lightguide structure comprising: a first portion disposed to receive light rays emitted by an external display, a second portion disposed to provide, to a second surface facing a viewer, the light rays from the first portion and ambient light, wherein the second portion has a plurality of first surfaces for reflecting light rays and at least one second surface which the light rays and the ambient light perpendicularly enter into and pass through, an intermediate portion disposed to connect between the first portion and the second portion and reflect the light rays from the first portion for transferring the light rays to the second portion.

Abstract: A method of making a security device, comprising: forming an array of primary focusing elements on a first region of a focusing element support layer, by applying at least one transparent curable material either to the focusing element support layer or to a casting tool carrying a surface relief over an area which includes at least the first region, the surface relief comprising portions corresponding to the primary focusing elements; forming the transparent curable material(s) with the casting tool; and curing the transparent curable material(s) so as to retain the surface relief in the first region; wherein the surface relief further includes a plurality of structures of greater depth than the height of the primary focusing elements such that the cured transparent material(s) include a plurality of features protruding above the height of the primary focusing elements between primary focusing elements of the array.

Abstract: Embodiments of the disclosure provide a fisheye lens. The fisheye lens can include a first lens group near an object side, a second lens group near an imaging plane, and an aperture diaphragm disposed between the first and second lens groups. The first lens group can include, disposed sequentially from the object side to the imaging plane, a negative meniscus spherical first lens, an aspherical second lens, and an aspherical third lens. The second lens group can include, disposed sequentially from the object side to the imaging plane, a positive meniscus spherical fourth lens, a fifth lens formed of a positive biconvex spherical lens and a negative biconcave spherical lens, and an aspherical sixth lens.

Abstract: Planar optical module (100, 100?) for capturing, converging and collimating incident light (3, 3?) with a variable incident direction comprising: —a first optical arrangement (10) with an optical layer able to converge the incident light-beam (3, 3?), forming thereby a converging light-beam (4, 4?) and —a second optical arrangement (20) placed downstream said first optical arrangement (10), said second optical arrangement (20) having an optical layer collimating said converging light-beam(s) (4, 4?), forming thereby a collimated and concentrated beam (5, 5?), wherein the first and second optical arrangements (10, 20) are movable one relative to the other such that the relative position of first and second optical arrangements (10, 20) allows said collimated and concentrated beam (5, 5?) to have an orientation which is, in a plane perpendicular to the main plane (P) of the planar optical module (100, 100?), predetermined, fixed and independent from the direction of the incident light (3, 3?).

Abstract: A liquid lens structure has an adjustable and continuous range of optical power. The liquid lens structure comprises a substrate layer and a deformable membrane which enclose a volume of liquid. The substrate layer is at least partially transparent in the optical band. The deformable membrane comprises a ground layer, two membrane layers, and two conductive layers. Each of the two conductive layers control electrical voltage applied to one of the membrane layers in reference to the ground layer, wherein each membrane layer deforms in response to applied electrical voltage. The deformation of the two membrane layers adjusts a curvature of the deformable membrane which provides the adjustable continuous range of optical power to the liquid lens structure.

Abstract: A zoom lens includes a unit LN, a unit LP and a rear group LR, and the rear group LR has a positive unit LRP on a side closest to an image, where the unit LRP includes a positive lens GRP that has a meniscus shape having a convex surface facing the image side thereof and made of resin material. Focal lengths of the zoom lens at wide-angle end, the unit LRP, and the unit LP, back focus at telephoto end, an amount of movement of the unit LRP when zooming from wide-angle end to telephoto end, thickness on an optical axis of the positive lens GRP, and a distance in optical axis direction between center on a lens surface on object side of the positive lens GRP and an end of an effective surface of the lens surface on the object side are each appropriately set.

Abstract: A display system is disclosed for use in an augmented reality display (30), the system comprises a waveguide (32) having a front surface and a rear surface. A front input projector (34) projects polychromatic light through a front surface, and a back input projector (36) projects polychromatic light through the rear surface. Input light impinges on an input grating (38) on a rear surface of the waveguide (32), and light travels through the waveguide by total internal reflection. An output grating (40) is provided for coupling light out of the waveguide. A plurality of front and back input projectors (34, 36) are provided in a staggered configuration along the width of the waveguide (32) and respective edges of adjacent front and back input projectors are aligned along the width of the waveguide to permit a continuous projection of light.

Abstract: A lens apparatus includes: an optical member; a driver that drives the optical member; a position detector that detects a position of the optical member; a target position deriver that sets a target position to which to drive the optical member; a speed deriver that derives a target speed for the driver to drive the optical member based on a difference between the target position and the position of the optical member; and a controller that controls the driver. The controller controls driving of the driver such that a speed of the optical member is equal to the target speed.