Abstract: Optical systems including first and second optical stacks and adapted to provide an adjustable dioptric correction are described. The first optical stack includes a first optical lens and a partial reflector. The second optical stack is convex along orthogonal first and second axes and includes a second optical lens and a reflective polarizer. The reflective polarizer has at least one first location having a radial distance r1 from an optical axis of the second optical stack and a displacement s1 from a plane perpendicular to the optical axis at an apex of the reflective polarizer, where s1/r1 is at least 0.1. A quarter wave retarder is disposed between the second optical stack and the first optical stack.

Abstract: An apparatus, system and method for microscopy. The apparatus, system and method includes a stage configured to receive an item; a tunable acoustic gradient index of refraction (TAG) lens having a first aspect positioned to image the received item, wherein the first aspect of the TAG lens is configured to have an optical power profile in accordance with an operational frequency of the TAG lens; one or more lenses configured to magnify an image of the received item at a viewing point; and at least one pulsed light source configured to illuminate the received item and to pulse at one or more points within the optical power profile of the TAG lens.

Abstract: Apparatuses, devices and systems and methods for microscopy and optical data storage in transparent media, as well as for laser material processing of transparent or semi-transparent materials. Optics for diffraction limited focusing inside transparent or semi-transparent media comprising aplanatic focusing optical system and positive meniscus lens where reciprocal positions of the components and a transparent medium are optimized with criterion of minimized aberration providing diffraction limited internal focusing at a given depth inside the said transparent medium. For modern high resolution microscopy the optical components have achromatic and apochromatic optical designs. Immersion in space between the meniscus lens and the transparent material is used to increase the system numerical aperture.

Abstract: Provided is a wire grid polarizing plate. The wire grid polarizing plate comprises a light-transmitting substrate and wire grid patterns which are disposed on the light-transmitting substrate, and which are arranged to transmit first polarized light and to reflect second polarized light polarized in a direction perpendicular to that of the first polarized light, the wire grid patterns comprising target patterns comprising conductive structures shaped as closed curves, at least one of the conductive structures surrounding another one of the conductive structures with a gap therebetween.

Abstract: A substrate, a plurality of mirrors disposed on one surface of the substrate to be separated from the substrate, a mirror support post disposed between the substrate and the mirror and connected to a part of the mirror to support the mirror, a first electrode disposed between a first portion of the mirror and the substrate on the substrate, a second electrode disposed between the substrate and a second portion facing the first portion are included. The mirror includes a thin portion in which a thickness of at least a part of an end portion of a rear surface of the mirror is thinner than a thickness of a middle of the mirror.

Abstract: In one aspect, structures are provided that comprise (a) a one-dimensional periodic plurality of layers, wherein at least two of the layers have a refractive index differential sufficient to provide effective contrast; and (b) one or more light-emitting nanostructure materials effectively positioned with respect to the refractive index differential interface, wherein the structure provides a polarized output emission.

Abstract: The invention provides an ultrasonic motor, which is an ultrasonic motor provided on a shaft end of a rotation shaft. An output shaft of the ultrasonic motor is connected to the rotation shaft, a stator is rotatably provided on the output shaft, a rotor is fixed to the rotation shaft, a vibration generating component for generating an ultrasonic vibration is provided on either one of the rotor or the stator. A whirl-stop unit is provided between the stator and a fixed side for supporting the rotation shaft: the whirl-stop unit has a joint holder provided on the fixed side and a connection element provided on the stator: the joint holder has a ball holder for pressing a metal ball to the connection element in a circumferential direction and a connection pin holding the connection element between the ball holder and the connection pin, spanning over the joint holder and capable of tilting.

Abstract: The present invention relates to a method of manufacturing a thin polarizer, including: forming a film laminate by attaching a polyvinyl alcohol-based film to at least one surface of a polymer film by using attraction force or an adhesive; swelling the film laminate so that a degree of swelling of the polyvinyl alcohol-based film is 0.36 to 0.44; dyeing at least one of iodine and a dichromatic dye on the film laminate; and stretching the film laminate.

Abstract: A Faraday rotator mirror, including: a polarizing beam splitter, a polarizing beam converging device made from birefringent crystal, a Faraday rotator, a reflecting mirror. In operation, light rays from an optical coupling element pass through the polarizing beam splitter, the polarizing beam converging device, the Faraday rotator, and the reflecting mirror, in that order, and then return back through the Faraday rotator, the polarizing beam converging device, and the polarizing beam splitter, in that order, and are output from the optical coupling element in reverse to the original incidence path.

Abstract: Electro-mechanical designs for MEMS scanning mirrors are described. In various embodiments, a driving coil may be situated on a reflective portion of a MEMS mirror. In some embodiments, a sensing coil may be situated partially or entirely on an outer frame portion of the MEMS mirror. Other embodiments are described and claimed.

Abstract: Methods for producing tooling and sheeting using laser writing techniques, and corresponding products thereof, are presented. In one embodiment, a seamless sheet having a plurality of microstructures formed in a continuous microstructured pattern is provided. In the methods described herein, a substrate having a photosensitive coating on a surface thereof is provided. A surface-relief microstructured pattern is produced in the photosensitive coating by selectively exposing the photosensitive coating to a beam of electromagnetic radiation. The exposed portions of the photosensitive coating are developed to form a microstructured pattern on the surface of the substrate. The microstructured pattern is then transferred into retroreflector tooling comprising the microstructured pattern on a surface thereof. A sheet containing the microstructured pattern on a surface thereof is then formed from the retroreflector tooling.

Abstract: The present application discloses a polarizing film and a display device including the polarizing film. The polarizer includes a transparent substrate; a linear polarizer disposed on the transparent substrate; an optical retardation film disposed on the transparent substrate; the linear polarizer including a first dielectric layer covered on the transparent substrate and a metal layer disposed on the first dielectric layer; and the optical retardation film including a second dielectric layer disposed on the transparent substrate to solve the mechanical, optical and lifetime issues faced to the conventional organic polarizing film, while solving the problem of the increased thickness of optical films owing to the manufacture and adhesion of polarizer and retardation film separately.

Abstract: A wire grid polarizer (20) and a fabrication method thereof,and a display device are provided. The fabrication method of the wire grid polarizer (20) includes: applying a mixture (100) including a polymeric monomer (101) and a metal particle (102) on a surface of a base substrate (01); performing a curing treatment on the mixture (100) at a predetermined position; and forming a wire grid pattern including protrusions (110) arranged at intervals on the surface of the base substrate (01). Problems of a complicated process, great difficulty and high cost in a fabrication process of the wire grid polarizer (20) are solved.

Abstract: A microscope illumination apparatus includes: a dark-field illumination unit including a light source that is arrangeable in an outer periphery of an observation light path of a microscope, the dark-field illumination unit being removably provided in the outer periphery of the observation light path; a detector that detects that the dark-field illumination unit has been arranged in a prescribed position of the outer periphery of the observation light path, and outputs a turn-on signal; and a controller that controls the light source to be turned on in accordance with the detection of the detector.

Abstract: A microscope includes: a sample placement part having a placement surface on which to place a sample and a bottom face opposite to the placement surface; an observation lens; and an optical unit for generating sheet light and use of the microscope. The microscope of an embodiment is arranged such that the sheet light enters the sample placement part from the bottom face and passing through the sample placement part to irradiate the sample, and fluorescence from the sample passes through the sample placement part toward the bottom face to be received by the observation lens. The microscope can, with this arrangement, utilize the advantages of a SPIM, and allows observation of a sample which observation is free from a restriction of the size of a sample.

Abstract: An apparatus for micro-electro-mechanical (MEMS) reinforcement is described herein. The apparatus includes a MEMS device and a stiffener. A micro scale mirror is to be embedded in a top layer of a substrate of the MEMS device. The stiffener is to be coupled to a back side of the MEMS device, wherein the stiffener is to stiffen the MEMS device via support of the MEMS device, without increasing a thickness of the MEMS device.

Abstract: A lens system includes a tube lens and a lens assembly, with the tube lens disposed between an optical sensor and the lens assembly. The lens assembly is disposed between the tube lens and an imaged object. In order to solve the problem of some lens systems having focal lengths that are shorter than the working distances of the lens systems, one aspect of the inventive subject matter described herein provides the lens assembly with a negative lens and plural positive lenses. A first positive lens is located between a second positive lens and an imaging plane, the second positive lens is located between the first positive lens and the negative lens, and the negative lens is located between the second positive lens and the tube lens.

Abstract: Disclosed are several technical approaches of using low coherence interferometry techniques to create an autofocus apparatus for optical microscopy. These approaches allow automatic focusing on thin structures that are positioned closely to reflective surfaces and behind refractive material like a cover slip, and automated adjustment of focus position into the sample region without disturbance from reflection off adjacent surfaces. The measurement offset induced by refraction of material that covers the sample is compensated for. Proposed are techniques of an instrument that allows the automatic interchange of imaging objectives in a low coherence interferometry autofocus system, which is of major interest in combination with TDI (time delay integration) imaging, confocal and two-photon fluorescence microscopy.

Abstract: A projection optical system is constituted by, in order from the reduction side, a first optical system constituted by a plurality of lenses for forming an image displayed by image display elements as an intermediate image, and a second optical system constituted by a plurality of lenses for forming the intermediate image on a magnification side conjugate plane. Conditional Formula (1) below is satisfied. 8.20<Im?·f2/f2<20.

Abstract: A selectively-absorptive wire grid polarizer comprising an array of parallel, elongated rods disposed over a surface of a transparent substrate with gaps between adjacent rods, each of the rods including a reflective wire sandwiched between two absorptive ribs. A method of making this wire grid polarizer. A use of this wire grid polarizer in an image projection system.