Abstract: A surfactant includes a hydrophobic functional group, a hydrophilic functional group and a linker disposed between the hydrophobic functional group and the hydrophilic functional group, and the linker is connected to the hydrophobic functional group and the hydrophilic functional group. The linker has a cleavable bond with a bond energy lower than a bond energy of a bond included in the hydrophilic functional group and a bond included in the hydrophobic functional group.

Abstract: An optical coherence tomography apparatus includes: an acquisition unit configured to split light from a light source into measurement light and reference light, and acquire a tomogram of an eye to be examined based on interfering light obtained by interference between the reference light and return light from the eye; a positional relationship changing unit configured to change a positional relationship between the eye and an optical system including an optical path of the measurement light; and a control unit configured to control the changing unit based on a difference in slant information of the eye between two tomograms acquired by the acquisition unit.

Abstract: A prop system for a secondary pair of eyeglasses to be worn over and in front of a primary pair of eyeglasses having a prop portion of substantially rigid material, the prop portion having an inward edge and an outward edge; and an attachment portion disposed on the outward edge wherein the attachment portion is affixable to a secondary pair of eyeglasses thereby providing a prop extending essentially orthogonally and inwardly from the secondary eyeglasses, wherein the prop portion may engage one or more upper surfaces of a primary pair of eyeglasses to support the secondary eyeglasses when placed over the primary pair of eyeglasses in a manner that avoids creating a sensation to a wearer of wearing two pairs of eyeglasses.

Abstract: A helmet or head-mounted apparatus has a visor or other curved optical element in front of at least one eye of a wearer, which element also is used as a waveguide. Image-bearing light is injected into the waveguide via an input diffractive element, and propagates through the visor to an output diffractive element which releases the light. The optical powers of the curved waveguide and the input and output diffractive elements are selected so that the released light is delivered as an image to the users eye.

Abstract: The invention relates to a method for determining the location of the ocular pivot point (ADL) in an eye (10) of a test person. In the method, the mean curvature (KH) of the cornea (14) of the eye (10) is determined. The mean phase error (PF) of the eye (10) is determined as is the eye length (LA) from the mean curvature (KH) and the mean phase error (PF). The location of the ocular pivot point (ADL) is determined from the eye length (LA).

Abstract: A system including spatial light modulators with multiple one-dimensional (1D) diffractor arrays and methods of operating the same are provided. In one embodiment, the system comprises a spatial light modulator (SLM) assembly including a plurality of one-dimensional (1D) diffractor arrays to modulate light from a light source, the plurality of 1D diffractor arrays integrally formed on a die; illumination optics disposed in a light path between the plurality of 1D diffractor arrays and the light source to illuminate a substantially linear portion of at least one of the plurality of 1D diffractor arrays; and imaging optics disposed in a light path between the SLM assembly and an image plane on a target-substrate, the imaging optics adapted to transmit modulated light from the SLM assembly to a substantially linear portion of the image plane. Other embodiments are also provided.

Abstract: Disclosed herein is a subminiature optical system including: a first lens group having positive refractive power; a second lens group having negative refractive power; and a third lens group having positive refractive power, wherein the second lens group is configured of a plurality of lenses of which facing surfaces are bonded to each other and the following Conditional Equation is satisfied: n1, n3>1.7??[Conditional Equation].

Abstract: The present invention provides an eyeglass frame securement apparatus comprising an eyeglass frame with upper and lower frames for eyeglasses to be mounted thereon, two outer sides of said upper and lower frames attached to eyeglass temples, a protection strip frame locked into inner circumference of said eyeglass frame; protruding pins extending forward and rearward from a center of the lower frame pivotally attached to the upper frame; a rib extending from outer sides of the upper frame and inserted into grooves to restrict the eyeglasses; protrusions on upper end of supporting shaft of the eyeglass temples inserted into the spaces on the outer side of said lower fame. Therefore, once the upper frame is completely assembled, said eyeglass temples can be outwardly bent to allow said protrusions on the upper end thereof to extend outward from the horizontal hole of the upper frame to restrict said eyeglass temples directionally.

Abstract: This disclosure relates to systems and/or methods for detection of eye blinking by interrogating a passive surface acoustic wave based contact lens using an interrogation signal and interpreting reflections of the interrogation signal from the passive surface acoustic wave based contact lens.

Abstract: An optical and mechanical design of a sealed, non-round fluid-filled lens capable of providing variation of optical power. The fluid lens includes at least three optical components: at least one mostly rigid optical disc, at least one mostly flexible optical membrane and a layer of a transparent fluid that is in communication via a fluid channel with a reservoir of excess fluid contained in a reservoir that can be accessed to augment the fluid volume inside the fluid lens to change the power of the fluid lens. The fluid lens is capable of providing correction of spherical and astigmatic errors, and utilizes contoured membranes to provide for a substantially constant desired spherical power over a substantially full field of view of a user.

Abstract: A photographing optical lens system includes, in order from an object side to an image side, a first lens element, a second lens element, a third lens element, a fourth lens element and a fifth lens element. The first lens element with positive refractive power has a convex object-side surface. The second lens element has negative refractive power. The third lens element has refractive power. The fourth lens element with negative refractive power is made of plastic material, and has a concave object-side surface and a convex image-side surface. The fifth lens element with negative refractive power is made of plastic material, and has a concave object-side surface and a concave image-side surface. At least one surface of the fourth through fifth lens elements is aspheric, and the image-side surface of the fifth lens element changes from concave at the paraxial region to convex at the peripheral region.

Abstract: An electrophoretic display device includes an array substrate, an opposing substrate, and an electrophoretic layer disposed between the array substrate and the opposing substrate. The array substrate includes a first base substrate having a plurality of pixel regions, and a pixel electrode having a plurality of electrode patterns disposed in each of the pixel regions. The opposing substrate includes a second base substrate positioned opposite to the first base substrate, and a common electrode disposed on a surface of the second base substrate that faces the first base substrate. The electrophoretic layer includes a plurality of polarity particles dispersed in a non-polar solvent. The common electrode includes a plurality of openings disposed in a region corresponding to each of the electrode patterns.

Abstract: A highly color saturated light modulator includes a transparent substrate, printed image layer and a protection layer on the printed surface. The degree of color saturation of images on the modulator is greater than 40% and overall transmission between 15% and 95%. Lighting devices with the light modulator can be designed to meet desired light emitting intensity and direction by integrating micro-structures to the transparent substrate.

Abstract: A methodology is provided for correcting the placement of a laser beam's focal point. Specifically, this correction is done to compensate for displacements of the focal point that may be caused when implant material (e.g. an Intraocular Lens (IOL)) is positioned on the optical path of the laser beam. The methodology of the present invention then determines a deviation of the laser beam's refracted target position (uncompensated) from its intended target position. A calculation of the deviation includes considerations of the laser beam's wavelength and refractive/diffractive characteristics introduced by the implant material. This deviation is then added to the refracted target position to make the refracted target position coincide with the intended target position of the focal point. The laser beam will then focus to its intended target position.

Abstract: The Multi-MOEMS display comprises at least two MOEMS, and at least one superposition layer. All MOEMS are illuminated by beams which incide with incidence angles larger than the deflection angle onto the mirrors in their ON-state for an improved separation of illumination and reflected modulated beams. The reflected ON-beams accordingly include a zenith angle with the normal of the mirror arrays of the MOEMS. The increased angle between the illumination and the modulated beam facilitates the separation of illumination and modulated beams and diminishes the optic limitations of light energy flux through this reflection at the modulators. The Multi-MOEMS display uncovers a solution for the geometric problems of arranging multiple MOEMS and superposition layers posed by the non-normal reflection of the modulated image beams, by matching the zenith angles and the azimuth angles in the superposition image, and by a defined position of the MOEMS relative to the superposition layer.

Abstract: A color electrophoretic display includes a substrate, a segment electrode circuit layer, a transparent electrode layer, an electrophoretic display medium layer, and a colored polymer film. The segment electrode circuit layer is disposed on the substrate and is configured to display a letter and/or a pattern. The transparent electrode layer is disposed opposing the segment electrode circuit layer, and the electrophoretic display medium layer is disposed between the segment electrode circuit layer and the transparent electrode layer. The electrophoretic display medium layer is controlled by an electric field that is produced and varied by the segment electrode circuit layer and the transparent electrode layer to change brightness. The color polymer film is disposed on the transparent electrode layer to produce color. The colored polymer film includes a polymer layer and pigment particles distributed in the polymer layer.

Abstract: Disclosed herein is an imaging lens unit, including: a first lens having a positive (+) power; a second lens having a negative (?) power; a third lens selectively having one of a positive (+) and negative (?) power; a fourth lens having a negative (?) power; and a fifth lens having a negative (?) power, wherein the first lens, the second lens, the third lens, the fourth lens, and fifth lens are arranged in order from an object to be formed as an image, and the fourth lens is concave toward an image side.

Abstract: This invention provides a contact lens for myopia control comprising: an object-side surface comprising a central zone, a transition zone and a peripheral zone which are concentric and have different refractive power, at least one of the three zones being aspheric; and an image-side surface; wherein the central zone provides correction power to focus a foveal image on the retina, the peripheral zone provides a myopic defocus effect by generating a para-fovea image in front of the retina, and the transition zone with one or more focuses provides a refractive power in diopter (D) ranging from +0.25 D to +8.00 D.

Abstract: Embodiments of the invention generally provide electrochromic devices and materials and processes for forming such electrochromic devices and materials. In one embodiment, an electrochromic device contains a lower transparent conductor layer disposed on a substrate, wherein an upper surface of the lower transparent conductor layer has a surface roughness of greater than 50 nm and a primary electrochromic layer having planarizing properties is disposed on the lower transparent conductor layer. The upper surface of the primary electrochromic layer has a surface roughness less than the surface roughness of upper surface of the lower transparent conductor layer, such as about 50 nm or less.

Abstract: In a virtual image display device, a mirror layer has a thickness of 50 nm or more to perform non-transparent reflection in a second ridge line vicinity area on a third reflection face side in a ridge line portion extending between the third reflection face and a second reflection face. Accordingly, reflectance of image light can be prevented from being decreased by the second ridge line vicinity area (that is, a peripheral portion on a light guide unit in the third reflection face), and thus stripe-shaped brightness unevenness extending in a longitudinal direction can be prevented from occurring on the viewed image. That is, in the image display device, it is possible to secure sufficient reflection even in the peripheral portion close to a boundary with the second reflection face with respect to the third reflection face, and also to display a bright image with little brightness unevenness.