Abstract:
Provided is a composition comprising a nonmicellar twisted nematic liquid crystal having cholesteric near infrared-reflecting properties and at least one near infrared absorptive material. This composition reduces the transmission of near infrared radiation. The composition can be used as a layer, optionally in conjunction with polymeric films, polymeric sheets, rigid sheets, and the like, to form multilayer laminates. In some embodiments these multilayer laminates are useful as solar control windows or window films to reduce energy consumption necessary to cool the interior of a structure such as an automobile or building.
Abstract:
A display panel is disclosed and comprising a display substrate, a light sensor, and a light absorption layer; the light sensor is formed in the display substrate and configured to sense ambient light; the light absorption layer is disposed on the display substrate and overlapped with the light sensor; and the material of the light absorption layer comprises at least one of an infrared light absorbent and an ultraviolet light absorbent.
Abstract:
A display device including a rear chassis, a display panel arranged in front of the rear chassis to display an image, a middle mold arranged between the display panel and the rear chassis and coupleable to the rear chassis, an optical member arranged between the rear chassis and the display panel, and a welding portion formed by laser-welding the display panel and at least one of the middle mold or the optical member.
Abstract:
A night vision imaging system (NVIS) compatible liquid crystal display (LCD) includes a backlight and an LCD panel. The LCD panel includes a color filter including a plurality of colored pixels. Each of the colored pixels in the plurality of colored pixels incorporates a near infrared (NIR) filter, capable of substantially blocking emissions from the backlight, including NIR emission between 650 nm and 930 nm, while maintaining high transmission of bands of visible light for producing a full color visual image.
Abstract:
Provided are a multilayered-coating system and a method of manufacturing the same. The multi-layered coating system includes: a layer 1 including a plurality of spherical voids with a radius a1 that are randomly distributed and separated from one another and a filler material with a refractive index n1 that is disposed in a space between the spherical voids; and subsequent layers expressed as the following word-equation, “a layer i located above a layer i−1 and including a plurality of spherical voids with a radius ai that are randomly distributed and separated from one another, and a filler material with a refractive index ni, the filler material disposed in a space between the spherical voids where i is an integer greater than 1”.
Abstract:
Various implementations described herein are directed to a marine display device. In one implementation, a marine display device may include a housing and a display panel disposed in the housing, where the display panel is configured to project one or more images relating to marine electronics data. The marine display device may also include an infrared filter coupled to the display panel and configured to block light from being applied to the display panel.
Abstract:
Transparent structures, electrochromic devices, and methods for making such structures/devices are provided. A transparent structure may include a transparent substrate having a plurality of micro- or nano-scale structures, at least one substance configured to block near-infrared or infrared radiation and partially cover at least substantial portions of the substrate and the plurality of micro- or nano-scale structures, and at least one photocatalyst configured to at least partially cover an outermost surface of the transparent structure.
Abstract:
A display device uses a multilayer film (104), which reflects (red) light having wavelengths between about 600 and 800 nm at a 60 degree angle of incidence (114), to protect a liquid christal panel (102) from heat and sun damage. The film (104) transmits light of the visible band with a wavelength between about 420 and 650 nm at normal incidence (116). The outermost surface (106) of the film (104) may be a hard coat (124). A metal oxide layer (120) and a metal layer (130) may be included to reflect IR light greater in wavelength than about 850 nm.
Abstract:
A liquid crystal lens includes a first light-pervious plate, second light-pervious plate opposite to the first light-pervious plate, a first electrode layer on the first light-pervious plate, a second electrode layer on the second light-pervious layer, a liquid crystal layer and a driving voltage unit. The first electrode layer includes a plurality of concentric, annular electrodes and is comprised of carbon nanotubes. The liquid crystal layer is sandwiched between the first and second light-pervious plates. The liquid crystal layer includes a plurality of annular regions spatially corresponding to the respective annular electrodes. A density of liquid crystal in the annular regions of the liquid crystal layer is different from each other. The driving voltage unit is configured for providing voltages between each of the annular electrodes and the second electrode layer for creating a gradient distribution of refractive index of the liquid crystal layer in radial directions.