Abstract: An optical scanning device includes a mirror that includes a mirror reflection surface, and torsion bars that support the corresponding sides of the mirror and cause the mirror to rotate. The torsion bars are formed of a silicon active layer whose surface is exposed.

Abstract: Various arrangements and methods are disclosed for forming one or more perforations on a substrate surface using a laser system, at least one rotating polygon mirror, and at least one other movable mirror. A rotating polygon mirror may be used to define a plurality of perforations in a row set or band on a substrate surface by incrementing (e.g., moving) a first mirror between a plurality of fixed (e.g., pointing) positions. A rotating polygon mirror may be used to define a plurality of perforations in a row set or band on a substrate using a first mirror that is maintained in a fixed (e.g., pointing) position. A first rotating polygon mirror and a second rotating polygon mirror may be used to define a plurality of perforations in a row set or band on a substrate surface, where the first and second polygon mirrors are used to define an extent of a given perforation in two dimensions on the substrate.

Abstract: An electronic device includes an analog to digital converter receiving an analog mirror sense signal from an oscillating mirror and generating a digital mirror sense signal therefrom, and a digital signal processing block. The digital signal processing block cooperates with the analog to digital converter to take a first sample of the digital mirror sense signal at a first time where a derivative of capacitance of the digital mirror sense signal crosses zero, take a second sample of the digital mirror sense signal at a second time between a peak of the digital mirror sense signal and the first time, and take a third sample of the digital mirror sense signal at a third time after the digital mirror sense signal has reached a minimum. Control circuitry determines an opening angle of the oscillating mirror as a function of the first, second, and third samples.

Abstract: A rearview device for a motor vehicle includes a moveable head assembly, an actuator assembly having a fixed part and a moveable part, the moveable part being attached to the head assembly, a motor cradle configured to attach the actuator assembly to the moveable head assembly. A method of assembling a rearview device comprises providing the rearview device and attaching the actuator assembly to the moveable head assembly using the motor cradle.

Abstract: The present application provides a replicating method and a replicating device of a transmission type holographic optical element capable of mass-replicating the transmission type holographic optical element by a continuous and economical process.

Abstract: According to an embodiment, a semiconductor device includes a first actuator, a second actuator, a first frame provided between the first actuator and the second actuator, a first connection member connecting the first actuator and the first frame to each other, a second connection member connecting the first actuator and the first frame to each other at a position different from a position at which the first connection member connects the first actuator and the first frame to each other, a third connection member connecting the second actuator and the first frame to each other, a fourth connection member connecting the second actuator and the first frame to each other at a position different from a position at which the third connection member connects the second actuator and the first frame to each other.

Abstract: An optical device comprises a printed circuit card comprising an image capture electronic circuit, a metal lens support comprising at least one optical lens, the lens support being mounted on the printed circuit card so as to align, on the optical axis of the device, the image capture electronic circuit and the optical lens; the device further comprises at least one first electrically conductive heating element on and in electrical contact with the printed circuit card, between the lens support and the printed circuit card, and bearing against the lens support, the first heating element being configured to have passed through it an electrical current coming from the printed circuit card.

Abstract: A retroreflective material having high retroreflective performance while being edible is provided with a reflector main body that has optical transparency. The reflector main body is formed from agar. One side of the reflector main body constitutes an incident surface where incident light enters into the reflector main body. The other side of the reflector main body is formed as a retroreflective surface that reflects incident light that has entered to an inner part of the reflector main body in a direction substantially parallel to an incident direction.

Abstract: A system that includes a substrate for microelectromechanical system (MEMS) scanning mirror systems is provided. The MEMS scanning mirror system includes a substrate that includes a ceramic body. An actuator frame is mounted on the ceramic body of the substrate. The actuator frame includes at least one moveable member. At least one actuator is operatively connected to the at least one moveable member such that the actuator is configured to move the at least one moveable member. A scanning mirror assembly is mounted to the at least one moveable member such that movement of the at least one moveable member moves the scanning mirror assembly.

Abstract: An image projection system according to the present disclosure includes a projection optical system and an eyepiece optical system. The projection optical system projects an image. The eyepiece optical system is configured separately from the projection optical system and is to be mounted on a head of a viewer. The eyepiece optical system includes at least one holographic element. The eyepiece optical system guides projection light from the projection optical system to a pupil of the viewer. The holographic element deflects first-order diffracted light toward the pupil of the viewer, and has a positive focal length for the first-order diffracted light. At a time of viewing of the image, the projection light enters the eyepiece optical system at an angle that is equal to or larger than ? expressed by the following expression, ?=arctan((3.

Abstract: The present disclosure relates to a microelectromechanical systems (MEMS) scanner that implements piezoelectric actuation principles to facilitate rotational displacement of a mirror device. The present disclosure includes a MEMS scanning device having a mirror device, a torsional beam structure, and piezoelectric actuators having a shape that facilitates torsional force to be applied to the torsional beam structure and cause the mirror device to rotate about a longitudinal axis. The MEMS scanning device may further include a lever device including multiple stages to both transfer torsional force from the actuators and prevent different actuators from countering torsional forces of other actuators. Moreover, the MEMS scanning device may further include sensor elements to measure torsional forces and control movement of the mirror device.

Abstract: A stay packing (12) includes a plate-shaped packing main body (31) formed to correspond to a stay attachment surface (22), and a lip part (35) formed in an annular shape along an outer peripheral portion of the packing main body (31) and formed to protrude from the packing main body (31) toward an outer panel, in which the lip part (35) includes two flexion parts (54a) and (54b) between a base, which is a portion connected to the packing main body (31), and a distal end thereof, and the flexion parts (54a) and (54b) are formed over the entire circumference of the lip part (35).

Abstract: A piezoelectric MEMS scanning mirror system is provided. In particular, the efficiency and life of the system are improved by use of new bonding methods. Mechanical and electrical connections between the actuator frame of a piezoelectric MEMS scanning mirror system and the piezoelectric actuators in the system may be created using an anisotropic conductive adhesive. An anisotropic conductive adhesive only conducts electricity across the bond line between a lower portion of the piezoelectric actuator and a top of the metal frame. One way this is done is to provide a sparse loading of conductive particles. When the piezoelectric element is compressed against the frame, the conductive particles only form a conductive path across the bond line. Grit blasting, sanding, or chemical etching may be used to roughen the metal surface prior to bonding. A surface roughness between 2 RMS and 6 RMS may be created on the metal frame.

Abstract: Methods and systems for using a MEMS mirror for steering a LiDAR beam and for minimizing statically emitted light from a LiDAR system are disclosed. A LiDAR system includes a light source that emits a light beam directed at a MEMS device. The MEMS device includes a manipulable mirror that reflects the emitted light beam in a scanning pattern. The MEMS device also includes a stabilization ring positioned adjacent to and at least partially surrounding the mirror. An attenuation layer is disposed on a top surface of the stabilization ring and is configured to attenuate light reflected by the stabilization ring.

Abstract: The present disclosure relates to a holographic projection device, a holographic projection method, and a holographic projection apparatus. The holographic projection device includes a first stereoscopic imaging device including a plurality of transparent pixel blocks; and a light emitting device including a plurality of light emitting units, wherein the plurality of transparent pixel blocks have a one-to-one correspondence with the plurality of light emitting units, and wherein for a light emitting unit A of the plurality of light emitting units, the light emitting unit A is configured to illuminate a transparent pixel block A, and the transparent pixel block A is a transparent pixel block corresponding to the light emitting unit A in the plurality of transparent pixel blocks.

Abstract: A scanning device for scanning an object in a scanning microscope includes at least one scanning unit configured to two-dimensionally scan the object using a light beam. The scanning unit includes at least one deflection element configured to deflect a light beam impinging thereon. The deflection element is rotationally symmetric in shape. At least one rotation device is configured to rotate the scanning unit about an axis of rotation so as to allow for image field rotation.

Abstract: An exterior rearview mirror assembly for mounting at a vehicle includes a mounting arm configured for attachment at an exterior portion of the vehicle, and a mirror head having a mirror casing, a mirror reflective element and a mirror actuator. The mounting arm is received through an aperture in the mirror casing and the mirror actuator is attached at the mounting arm inside the mirror casing. The mirror actuator is electrically operable to adjust the mirror reflective element and the mirror casing relative to the mounting arm. The aperture allows for movement of the mirror casing relative to the mounting arm during operation of the mirror actuator. A powerfold actuator may be operable to pivot the mirror head relative to the base portion between a folded or non-use position and an extended or use position.

Abstract: A scanning module (100) for a light scanner (99) comprises a base (141) and an interface element (142) which is configured to secure a mirror surface (151). The scanning module (100) also comprises at least one support element (101, 102) which extends between the base (141) and the interface element (142) and has an extension perpendicular to the mirror surface (151) which is no less than 0.7 mm. The base (141), the interface element (142) and the at least one support element (101) are integrally formed.

Abstract: A near-eye display assembly presented herein includes an electronic display, an optical assembly, and scanning assembly. The electronic display has a first resolution. The optical assembly controls a field of view at an eye box and directs a plurality of light rays emitting from the electronic display toward the eye box. The scanning assembly shifts a direction of at least one of the light rays in accordance with emission instructions such that a virtual display is presented to the eye box, the virtual display having a second resolution greater than the first resolution. The display assembly can be implemented as a component of a head-mounted display of an artificial reality system.

Abstract: A modular imager assembly includes a housing configured for removable attachment to a vehicle windscreen and for removable attachment with a rearview assembly. An imager is disposed within the housing and is in optical communication with an aperture extending into the housing. A controller is disposed within the housing and is operably coupled with the imager and a vehicle headlamp. The controller is operable to control an operation state of the vehicle headlamp in response to image data received by the imager.