An optical system is provided, including a first movable part for connecting an optical element; a first base, wherein the first movable part is movable relative to the first base; and a first driving assembly for driving the movable part to move relative to the first base. The optical system further includes a light quantity control mechanism for controlling the quantity of light entering the optical element. The light quantity control mechanism further includes a base seat and a light quantity control assembly at least partially movable relative to the base seat. The optical system further includes a second driving assembly for controlling the light quantity control assembly.

An optical projection device, which effectively suppresses variation in aberration due to irregularities in installation positions of lens groups which form an optical projection system, and a projector which includes the optical projection device are provided. In a lens group, which includes a diaphragm, in an optical projection device which includes a plurality of lens groups, a lens frame is divided between the diaphragm and a lens which is adjacent to the diaphragm, one lens frame which is acquired through the division includes an adjustment portion, which maintains a position of an optical axis to be adjusted, with respect to the other lens frame which is acquired through the division.

Systems, devices, and techniques for creating blind annular vias for metallized vias are described. For example, a vortex beam may be applied to an optically transmissive substrate, where the vortex beam may modify a portion of the substrate in an annular shape. The annular shape may extend from a surface of the substrate to a depth that is less than a thickness of the substrate, and the annular shape may have an annular width (e.g., a ring width) that is the same for various diameters of the annular shape. A blind annular via may be formed by etching the modified portion of the substrate, where the blind annular via may include a pillar comprising the same material as the surrounding substrate. In addition, a metallized annular via may be created by filling the blind annular via with a conductive material, and removing a portion of the substrate opposite the surface.

An imaging device, an adjustment method, and an adjustment program can acquire multispectral images having good image quality. The imaging device is disposed on an image side of another optical system, and includes a multispectral camera that acquires images in a plurality of wavelength ranges, a field lens that relays the other optical system to the multispectral camera, and an adjustment mechanism that adjusts a conjugate relationship between an emission pupil position of the other optical system and an incident pupil position of the multispectral camera. The multispectral camera includes: a wavelength polarizing filter unit that includes an optical member disposed at a pupil position or near the pupil position and including a plurality of aperture regions having different centroids, a plurality of optical filters arranged in the aperture regions, and a plurality of polarizing filters arranged in the aperture regions; an imaging element; and a processor.

A head-mounted display (HMD) includes an electronic viewfinder. An angle selection type transmission element is provided on an optical path of the electronic viewfinder. The angle selection type transmission element is provided at a location facing an eyepoint and includes a plurality of opening portions as a limiter that limits a passage direction of light to a predetermined range. In the angle selection type transmission element, limitation angle range in the passage direction of the light is different in at least two regions and light in a direction other than the eyepoint can be limited or blocked.

An imaging lens includes a lens element, a light blocking sheet, and a lens barrel accommodating the lens element and the light blocking sheet. The light blocking sheet includes a first object-side surface, a first image-side surface, a first inner ring surface, a first microstructure, and a first nanostructure layer. The first image-side surface is opposite to the first object-side surface. The first inner ring surface is located between the first object-side surface and the first image-side surface and defines a first light passage opening. The first microstructure is disposed on the first object-side surface or the first image-side surface. The first microstructure has a plurality of protrusions. The first nanostructure layer is disposed on the first inner ring surface. The first nanostructure layer has a plurality of ridge-like protrusions extending non-directionally.

A method for controlling an optical element driving mechanism, including controlling a driving assembly by a control assembly to drive a movable to move relative to a fixed portion. The movable portion is used for connecting to an optical element, and the movable portion is movable relative to the fixed portion.

A window panel including a base substrate comprised of a transmission area and a bezel area adjacent to the transmission area, and a light-shielding pattern disposed on the base substrate overlapping the bezel area. The light-shielding pattern includes a first light-shielding pattern disposed on the base substrate and having a first width extending from a first side of the base substrate to a second side of the base substrate, beneath the bezel area of the base substrate, and a second light-shielding pattern disposed on the first light-shielding pattern and having a second width extending from the first side of the base substrate to the second side of the base substrate, beneath the bezel area of the base substrate, wherein the second width is different from the first width. The first light-shielding pattern and the second light-shielding pattern including different materials.

A variable aperture lens and methods of forming such lenses are disclosed. More particularly, embodiments of the variable aperture lens include an electro-optic aperture sandwiched between a front lens and a rear lens along an optical axis. The front lens or the rear lens may include multiple lens layers having different optical properties to provide for a low z-height, optically aligned, variable aperture lens.

Light-absorbing flange lenses that may be used in the lens stacks of compact lens systems. In a light-absorbing flange lens, the effective area of the lens is composed of a transparent optical material, and at least a portion of the flange of the lens is composed of an optical material that absorbs at least a portion of the light that enters the flange. Using light-absorbing flange lenses may allow the lens barrel to be eliminated from the lens system, thus reducing the X-Y dimensions of the lens system when compared to conventional compact lens systems that include a lens stack enclosed in a lens barrel. In addition, using a light-absorbing material in the flanges of the light-absorbing flange lenses may reduce or eliminate optical aberrations such as lens flare, haze, and ghosting in images.