Abstract: Disclosed herein are laser scanning systems and methods of their use. In some embodiments, laser scanning systems can be used to ablatively or non-ablatively scan a surface of a material. Some embodiments include methods of scanning a multi-layer structure. Some embodiments include translating a focus-adjust optical system so as to vary laser beam diameter. Some embodiments make use of a 20-bit laser scanning system.

Abstract: A MEMS device includes a fixed structure and a mobile structure with a reflecting element coupled to the fixed structure through at least a first deformable structure and a second deformable structure. Each of the first and second deformable structures includes a respective number of main piezoelectric elements, with the main piezoelectric elements of the first and second deformable structures configured to be electrically controlled for causing oscillations of the mobile structure about a first axis and a second axis, respectively. The first deformable structure further includes a respective number of secondary piezoelectric elements configured to be controlled so as to vary a first resonance frequency of the mobile structure about the first axis.

Abstract: Embodiments of the disclosure generally relate to a reflector for use in a thermal processing chamber. In one embodiment, the thermal processing chamber generally includes an upper dome, a lower dome opposing the upper dome, the upper dome and the lower dome defining an internal volume of the processing chamber, a substrate support disposed within the internal volume, and a reflector positioned above and proximate to the upper dome, wherein the reflector has a heat absorptive coating layer deposited on a side of the reflector facing the substrate support.

Abstract: An adjustable rearview mirror that is designed to quickly transition between transparent and reflective states. The apparatus is configured to resemble traditional rearview mirrors used in vehicles. The apparatus includes a window mount, a pivoting connection arm, and a user controlled mirror panel. The window mount connects the rearview mirror to the windshield of a vehicle. The pivoting connection arm enables a user to reposition the rearview mirror at will. The user controlled panel can be placed into a reflective or a transparent state based on user input. A user is able to gain a relatively unhindered view of traffic through a vehicle windshield.

Abstract: In order to allow precise observation of a specimen at an observation point with a desired depth without changing the working distance of an objective optical system while employing a simple configuration, a laser scanning microscope according to the present invention includes an objective lens having a plurality of optical elements that are disposed with gaps therebetween in an optical-axis direction and that condense laser light emitted from a light source onto a specimen and also having an adjustment ring that allows changing of the focal point by moving the optical elements in the optical-axis direction; a scanner that has a galvanometer mirror capable of oscillating about a predetermined oscillation axis and that scans the laser light condensed onto the specimen by the objective lens in accordance with an oscillation angle of the galvanometer mirror; a light detecting unit that obtains image information of the specimen on the basis of return light returned from the specimen scanned with the laser light;

Abstract: A hybrid organic-inorganic micromirror device includes a micromirror comprising an inorganic material positioned above an elastomeric substrate. The micromirror is supported on an underside thereof by a conductive elastomeric support protruding from the elastomeric substrate. The conductive elastomeric support may function as a universal joint and is rendered electrically conductive by an electrically conductive coating thereon. A plurality of electrodes are disposed on the elastomeric substrate under the micromirror. The electrodes are spaced apart from each other and from the micromirror and are arranged around the conductive elastomeric support. Each electrode comprises an inorganic material and is in electrical contact with an elastomeric contact region protruding from the elastomeric substrate. When a voltage bias is applied between the micromirror and one or more of the electrodes, the micromirror is electrostatically actuated to move in a predetermined direction.

Abstract: An electromagnetic energy-absorbing optical product useful particularly for automotive and architectural window films is disclosed. The electromagnetic energy-absorbing optical product includes a polymeric substrate and a composite coating with the composite coating including first and second layers each containing a binding group component which together form a complimentary binding group pair.

Abstract: An infinity mirror includes a light-transmissible and reflective layer, a reflective layer, a light-transmissible layer and at least one light-emitting element. The light-transmissible and reflective layer is disposed on a top surface of the light-transmissible layer. The reflective layer is disposed on a bottom surface of the light-transmissible layer. The at least one light-emitting element emits a light beam. The light-transmissible layer includes a pattern zone and a non-pattern zone. There is a height difference between the pattern zone and the non-pattern zone of the light-transmissible layer. The infinity mirror can provide a multi-mirror image effect.

Abstract: A head mounted display device includes a display panel and a lens assembly mounted so that an optical axis of the lens assembly intersects the display panel. The lens assembly includes a lens body having a surface facing the display panel and defining Fresnel prisms. A Fresnel prism of the Fresnel prisms has a first facet angle when viewed in a first cross-section and has a second facet angle when viewed in a second cross-section parallel to the first cross-section. The first facet angle is different than the second facet angle.

Abstract: A device disclosed herein includes a feedback measuring circuit to measure a signal flowing through a movable MEMS mirror. Processing circuitry determines a time at which the signal indicates that a capacitance of the movable MEMS mirror is substantially at a maximum capacitance. The processing circuitry also determines, over a window of time extending from the time at which the signal indicates that the capacitance of the movable MEMS mirror is substantially at the maximum to a given time, a total change in capacitance of the movable MEMS mirror compared to the maximum capacitance. The processor further determines the capacitance at the given time as a function of the total change in capacitance, and determines an opening angle of the movable MEMS mirror as a function of the capacitance at the given time.

Abstract: A multilayer thin film that reflects an omnidirectional high chroma red structural color. The multilayer thin film may include a reflector layer, at least one absorber layer extending across the reflector layer, and an outer dielectric layer extending across the at least one absorber layer. The multilayer thin film reflects a single narrow band of visible light when exposed to white light and the outer dielectric layer has a thickness of less than or equal to 2.0 quarter wave (QW) of a center wavelength of the single narrow band of visible light.

Abstract: The present invention discloses a method for detecting influence on a laser from back-reflected light of the laser and a detection device.

Abstract: According to the present invention there is provided a method of controlling the position of a MEMS mirror in a MEMS device, wherein the MEMS device comprises, a MEMS mirror, a magnet which provides a magnetic field (B), an actuating means which operatively cooperates with the MEMS mirror so that it can apply a force to the MEMS mirror which can tilt the MEMS mirror about at least one rotational axis when the actuating means is provided with a drive signal, wherein the magnitude force applied by the actuating means to the MEMS mirror is dependent on the amplitude of the drive signal, and a detection coil which is mounted on the MEMS mirror, the method comprising the steps of, detecting a change in the resistance (R) of the detection coil so as to detect a change in temperature of the MEMS mirror; determining the drive signal amplitude required to maintain the MEMS mirror at a predefined angular position (?); providing the actuating means with a drive signal which has an amplitude which is equal to the determi

Abstract: An optical element is configured by connecting a plurality of tiles each constituted by a plurality of reflective optical elements, and is formed in a shape having a plane surface. The tiles configuring the optical element are formed such that outer shapes on the plane surface of the tiles have at least two different triangular shapes, while an end surface of each tile is provided with a light shielding part.

Abstract: A method for producing a colloidal alcoholic suspension of fluorine-doped SnO2 particles. It also pertains to the colloidal suspension thus obtained and to its uses, especially in the manufacture of an antistatic coating for an optical article, such as an ophthalmic lens.

Abstract: A mirror drive device is provided as one capable of efficiently gaining a driving force. The mirror drive device 1 has a fixed frame 5; a movable portion 7 supported so as to be swingable relative to the fixed frame 5, through torsion bars 10a, 10b extending on an identical straight line, and being of a circular shape; a mirror 9 arranged on a principal surface 7a of the movable portion 7; and a permanent magnet 3 forming a magnetic field around the movable portion 7; the movable portion 7 has a drive coil 12 arranged below the mirror 9; the drive coil 12 is of a 2n-sided polygon shape (where n is an integer of 3 or more) when viewed from a direction orthogonal to the principal surface 7a, at least one side of which is orthogonal to a direction of the magnetic field F.

Abstract: A flat lens system includes a wedge-shaped refractive material having a first surface and a second surface opposite to the first surface for refracting incident light beams from an object having a width of Y, from the first surface towards the second surface; a reflective material positioned at the second surface of the wedge-shaped refractive material for reflecting the refracted light beams at a first angle toward the first surface, wherein the reflected light beams are refracted from the first surface at a second angle to form an image of the object having a width of X and including chromatic aberrations; and an apparatus for processing the image of the object to reduce said chromatic aberrations.

Abstract: What is proposed is: a micromirror arrangement which comprises: a first spring-mass oscillator, which has an oscillatory body forming a mirror plate (1) and first spring elements (2); a second spring-mass oscillator, which has a drive plate (3) and second spring elements (4) and which is connected to a carrier arrangement (5, 8, 9) via the second spring elements (4), wherein the first spring-mass oscillator is suspended in the second spring-mass oscillator via the first spring elements (2); and a drive arrangement (11), which is assigned to the drive plate and is designed to cause the drive plate (3) to oscillate.

Abstract: A device described herein includes a movable MEMS mirror, with a driver configured to drive the movable MEMS mirror with a periodic signal such that the MEMS mirror oscillates at its resonance frequency. A feedback measuring circuit is configured to measure a signal flowing through the movable MEMS mirror. A processor is configured to sample the signal at first and second instants, generate an error signal as a function of a difference between the signal at the first instant in time and the signal at the second instant in time, and determine the opening angle of the movable MEMS mirror as a function of the error signal.

Abstract: A micromechanical device for projecting an image and for analyzing an optical spectrum and a corresponding manufacturing method. The device includes: a first light providing unit by which a first light beam is providable to the device; a diffraction unit for diffract the first light beam provided to the device as a function of a diffraction property of the diffraction unit; a second light providing unit by which a second light beam is providable to the device; a micromirror by which the second light beam provided to the device is variably deflectable as a function of a position and/or an orientation of the first micromirror; and a first actuator by which the adjustable diffraction property of the optical diffraction unit and also the position and/or the orientation of the micromirror are adjustable.