Abstract: The invention relates to a head-up display (1) comprising: a reflecting mirror (9) held by a mirror holder (15) articulated about a pivoting axis (17); and a motor-driven system (31) for pivotably moving said reflecting mirror (9), comprising a motor unit (33), characterised in that the motor-driven system (31) comprises a connecting rod (35) extending in a direction perpendicular to the pivoting axis (17), the first end portion (35) of said connecting rod being engaged with the mirror holder (15) in an articulated manner, and a second end portion (39) thereof, opposite the first (37), being engaged with a rotary output body (47, 49) of the motor unit (33).

Abstract: Disclosed are a protective film for a polarizer with superior optical and mechanical properties, a polarizing plate including the same and a display device including the same.

Abstract: Disclosed are a protective film for a polarizer with superior optical and mechanical properties, a polarizing plate including the same and a display device including the same.

Abstract: A prism group, configured to cover a portion of a visible area and a portion of a non-visible area of a display module, includes a first prism and a second prism. The first prism disposed on the visible area includes a main body and a platform. The main body has a first light incident surface, a first light emitting surface and a first inclined surface. The first light incident surface faces to the visible area. The first light emitting surface is nearby the non-visible area and connected to the first light incident surface. The first inclined surface is connected between the first light incident surface and the first light emitting surface. The platform is opposite to the non-visible area and connected to the first light emitting surface. The second prism is disposed between the non-visible area and the platform. A display device having the prism group is also provided.

Abstract: An optical scanning apparatus includes: an array of optical emitters to provide a plurality of optical beams; a plurality of corresponding microlenses to receive the optical beams; and a variable collimator to receive the plurality of optical beams from the microlenses. The microlenses and variable collimator are arranged to decouple the illumination spot size of the optical beams from the illumination spot separation of the optical beams such that the illumination spot size and the illumination spot separation at a scanning surface are independently controllable.

Abstract: The present invention addresses the problem of providing a head-up display device with which the display quality of a display object can be improved. A mirror holder 30 supporting a concave mirror is equipped with a protruding piece that protrudes from the approximate center of the holder width, which is defined along a rotational axis, and this protruding piece is moved by a position adjustment means. Stress acting on the mirror holder from the protruding piece is uniform in the left and right directions from the center of the mirror holder. Consequently, twisting at the location of the mirror holder is significantly reduced, so the driver is able to view a display object for which distortion has been suppressed, and the display quality of the display object is improved.

Abstract: Provided is an optical scanner including a movable portion, a frame body portion, a first axis portion that connects the movable portion and the frame body portion and oscillatably supports the movable portion around a first oscillation axis, a support portion, and a second axis portion that connects the frame body portion and the support portion and oscillatably supports the frame body portion around a second oscillation axis, in which, when a distance between an end portion of the movable portion in a direction following the second oscillation axis and the frame body portion is defined as L1, and a distance between an end portion of the frame body portion in a direction following the first oscillation axis and the support portion is defined as L3, a relationship corresponding to 1<L1/L3<5 is satisfied.

Abstract: A waveguide display includes a light source, a conditioning lens assembly, a scanning mirror assembly, and a controller. The light source includes a plurality of source elements that are configured to emit image light in accordance with scanning instructions. The conditioning lens assembly transmits conditioned light based in part on the image light. The scanning mirror assembly scans the conditioned image light to particular locations as scanned image light in accordance with scanning instructions. The output waveguide includes an input area and an output area, receives the scanned image light emitted from the scanning mirror assembly at the input area, and outputs the expanded image light from a portion of the output area based in part on a direction of the expanded light output from the scanning mirror assembly. The controller generates the scanning instructions and provides the scanning instructions to the light source and the scanning mirror assembly.

Abstract: A scanning optical system, includes a mirror unit equipped with a first mirror surface and a second mirror surface each of which inclines to a rotation axis; and a light projecting system which includes at least one light source to emit a light flux toward the first mirror surface. A light flux emitted from the light source is reflected on the first mirror surface of the mirror unit, thereafter, reflected on the second mirror surface, and then, projected so as to scan in a main scanning direction onto an object in accordance with rotation of the mirror unit, and the light flux reflected on the second mirror surface is polarized in a range within an angle of ±30 degrees to a direction perpendicular to the main scanning direction on the object side.

Abstract: High resolution printing systems that utilize high power laser diode bars and digital mirror devices (DMD) require side-by-side stacking of illumination modules to stitching of the image from each module to form a longer total image width. An inline illumination optical system having a refractive prism and Total Internal Reflection (TIR) prism pair with an air gap along with a light guide transporting light beams at a compound angle to the prism pair eliminates the need for any axial rotation of the laser and light guide, and enables side-by-side module stacking. The illumination optical system includes an illumination module having a light source, the light guide, a DMD array and a Refractive TIR (RTIR) prism. The system also includes a DMD housing containing the DMD array and having a width within which the illumination module is confined to allow side-by-side stacking.

Abstract: A mirror reflective element suitable for use in an exterior rearview mirror assembly of a vehicle includes a glass substrate having a first side and an opposing second side. The mirror reflective element has a principal reflector portion and an auxiliary reflector portion. The auxiliary reflector portion includes a curved recess established at the second side of the glass substrate. An auxiliary mirror metallic reflector is coated at the curved recess at the second side of the glass substrate and a principal mirror metallic reflector is coated at the principal reflector portion. The mirror reflective element is configured so that, when an exterior rearview mirror assembly equipped with the mirror reflective element is normally mounted at a side of a vehicle, the curved recess is disposed at an outboard upper region of the mirror reflective element relative to the side of the equipped vehicle.

Abstract: The assembly to homogenize a light beam, especially from an excimer laser, has at least two optical functional surfaces (26) in succession along the light path (z). Two groups of refractive or diffractive imaging elements are at the optical surfaces as cylinder lenses (30, 30?, 32), with at least two imaging elements of different characteristics within at least one of the groups. The light beam is finally carried through a Fourier lens (28) to the working plane (29).

Abstract: There is provided an illumination device (100) comprising: a substrate (104); an optically transmissive first layer (106) arranged on the substrate; a photon emitting layer (108), arranged on the optically transmissive first layer and comprising a photon emitting material configured to receive energy from an energy source and to emit light having a predetermined wavelength; a periodic plasmonic antenna array, arranged on the substrate and embedded within the first layer, and comprising a plurality of individual antenna elements (114) arranged in an antenna array plane, the plasmonic antenna array being configured to support a first lattice resonance at the predetermined wavelength, arising from coupling of localized surface plasmon resonances in the individual antenna elements to photonic modes supported by the system comprising the plasmonic antenna array and the photon emitting layer, wherein the plasmonic antenna array is configured to comprise plasmon resonance modes such that light emitted from the plasm

Abstract: A method and apparatus for performing foci array scanning using at least one adjustable or tilting medium is disclosed. The medium can be controllably tilted in order to translate a beam of electromagnetic radiation perpendicularly to its propagation, and upon exiting the medium, will propagate in the original, incoming direction. This allows the apparatus that emits the radiation, such as a laser, to remain stationary and still scan a 2D array. Additionally, the reflected fluorescence light undergoes the opposite shift to “reverse” the scanning shift and bring the beamlets back in line with a lenselet array. So the collection fibers can remain static and collect light from different spots on the sample from during the scan.

Abstract: A display apparatus and an electronic device are provided, which belong to the field of display technology. The display apparatus comprises a light-converging layer configured to refract the light in a first designated direction, wherein the first designated direction is a direction whose angle with a straight ahead direction of the display apparatus is less than a designated angle, and the straight ahead direction is a direction perpendicular to a plane where the light-converging layer is located; and a light-emitting layer positioned below the light-converging layer and configured to emit light.

Abstract: The present disclosure relates to optical systems, specifically light detection and ranging (LIDAR) systems. An example optical system includes a laser light source operable to emit laser light along a first axis and a mirror element with a plurality of reflective surfaces. The mirror element is configured to rotate about a second axis. The plurality of reflective surfaces is disposed about the second axis. The mirror element and the laser light source are coupled to a base structure, which is configured to rotate about a third axis. While the rotational angle of the mirror element is within an angular range, the emitted laser light interacts with both a first reflective surface and a second reflective surface of the plurality of reflective surfaces and is reflected into the environment by the first and second reflective surfaces.

Abstract: An electrowetting display comprises a support plate on which individual electrowetting pixels separated from one another by pixel walls are formed. Pixel walls including different layers are disposed on the first support plate and separate adjacent pixel regions from each other. The first layer of a pixel wall comprises a first material having a first color and a second layer of the pixel wall comprises a second material having a second color that is different from the first color. Instead of using black matrix to reduce photo crosstalk, the pixel walls of the different layers absorb light colors that are not intended to reach the respective pixels. A fluid is disposed between the first support plate and a second support plate and at least partially surrounds the first wall and the second wall.

Abstract: A light deflecting device which suppresses a vibration caused by swing of a light deflecting unit and transmitted to a fixed unit and prevents noise from being made on a housing to which the fixed unit is attached, including a light deflecting unit having paired beams on both sides of a movable unit having a light reflecting unit and a coil, and a fixed unit to which the light deflecting unit is swingably fixed through the beams and which includes a magnetic field forming unit, swings the movable unit with the beams as torsional rotation axes by an electromagnetic force generated by a driving current flowing to the coil and a magnetic field formed by the magnetic field forming unit, and a counter swing member in the fixed unit to be swung in a reverse phase to the light deflecting unit so it is opposed to the light deflecting unit.

Abstract: Wing mirror unit, drive construction, and rotation sensor The invention relates to a wing mirror unit (1) for a motor vehicle. The unit comprises a mirror housing support (3) for attachment to a body (4) of the motor vehicle (2). The wing mirror unit further comprises a mirror housing (5) supported by the mirror housing support and pivotably arranged with respect to said support around a rotation axis (6) extending substantially in an upward direction. Furthermore, the unit comprises a drive, preferably an electric drive, for pivoting the mirror housing between a folded-out position of the mirror housing, in which the mirror housing extends substantially in a direction (7) away from the body of the motor vehicle, and a folded-in position of the mirror housing, in which the mirror housing projects less far and extends in a substantially rearward direction more alongside the body of the motor vehicle, and/or for pivoting the mirror housing between the folded-in position and the folded-out position.

Abstract: A near-eye optical display system utilizes a compact display engine that couples image light from an imager to a waveguide-based display having diffractive optical elements (DOEs) that provide exit pupil expansion in two directions. The display engine comprises a pair of single axis MEMS (Micro Electro Mechanical System) scanners that are configured to reflect the image light through horizontal and vertical scan axes of the display system's field of view (FOV) using raster scanning. The MEMS scanners are arranged with their axes of rotation at substantially right angles to each other and operate with respective quarter wave retarder plates and a polarizing beam splitter (PBS) to couple the image light into an in-coupling DOE in the waveguide display without the need for additional optical elements such as lenses or relay systems.