Abstract: Systems and methods for optical pulse stretching or compression in time are provided. An apparatus of the subject invention can operate as an optical dispersive element for optical pulse stretching or compression in time, as well as laser scanning in space. An apparatus can include a spatial disperser arranged to divide a collimated optical pulsed beam into an array of collimated beams with equally spaced angles, a beam shaper configured to control the spreading angle of the beam array, and a cavity to sequentially reflect the individual beams within the beam array. The cavity can include two non-parallel surfaces, such as two non-parallel mirrors.

Abstract: A display panel and a display device are disclosed. The display panel comprises: a first substrate and a second substrate that are cell-assembled together; a first polarizer that is disposed on a lower side of the first substrate. The first substrate and the second substrate are sealed by a sealing material disposed in a periphery region of both the first substrate and the second substrate. A display area is an area on the first substrate inside the sealing material and a first non-display area is an area that is aligned with the second substrate on the first substrate and outside of the sealing material. The first substrate extends outward on a side of the first non-display area to protrude out of the second substrate; the first polarizer extends outward on the side of the first non-display area to protrude out of the second substrate.

Abstract: An optically variable device and method of manufacturing the device is disclosed, the device including a plurality of zero-order diffraction grating elements some of which are modulated such that a coloured at least partially polarized image is visible to a person viewing the device, observing a first optically variable effect when the device is rotated about an axis substantially perpendicular to the plane, and a second optically variable effect when the device is viewed under polarized light and rotated about an axis substantially perpendicular to or parallel with the plane. The device is particularly suitable for security documents such as bank notes. Preferably, the first optically variable effect is produced by a change in brightness and/or color of the grating elements and the second optically variable effect may likewise be produced by a change in brightness and/or color of the grating elements.

Abstract: A method of automatically detecting a retinal feature using an ophthalmic imaging system can include: acquiring an optical coherence tomography (OCT) image of a retina; segmenting the OCT image; generating a metric based on the segmented OCT image; detecting the retinal feature based on the metric; and providing an indication of the detected retinal feature to a user. An ophthalmic imaging system can include: an OCT system configured to acquire an image of a retina; a computing device coupled to the OCT system and configured to segment the image, generate a metric based on the segmented image, and detect a retinal feature based on the metric; and an audio/visual/tactile device in communication with the computing device and configured to provide at least one of an audio, visual, and tactile indication of the detected retinal feature to a user.

Abstract: A photography or videography imaging system includes a panoramic converter that can be used with a user-selected camera lens. The panoramic converter includes a dome port and a corrector group of lenses that corrects the aberrations caused by the dome port when the imaging system is placed in a liquid. The corrector group compensates a field curvature produced by dome port while preserving the angles, relative to an optical axis of the panoramic converter, of propagation paths of light rays entering the dome port. The angle, relative to the optical axis, of the propagation path of a light ray in the liquid prior to entering the dome port is approximately the same as the angle, relative to the optical axis, of the propagation path of the light ray propagating toward the camera lens after exiting the corrector group of lenses.

Abstract: An optical absorber includes a first light-absorbing body which receives light incident from an entrance aperture and partially absorbs and reflects the incident light, and a second light-absorbing body which partially absorbs the incident light reflected by the first light-absorbing body and partially reflects the incident light toward the first light-absorbing body. The reflectance and light resistance of the first light-absorbing body are set higher than the reflectance and light resistance, respectively, of the second light-absorbing body.

Abstract: A panel assembly includes a transparent cover, a display module, a decorative layer, and a Fresnel lens structure. The transparent cover has a lower surface. The display module is disposed under the lower surface. The decorative layer is disposed on the lower surface. The Fresnel lens structure is located above the display module. Besides, an electronic device includes a frame, a housing, and the above panel assembly, and the housing and the panel assembly are installed in the frame.

Abstract: A lens barrel includes a filter ring retainer, an OIS base frame, and a ring-shaped filter ring. The filter ring retainer has a male screw. The OIS base frame has a female screw locking the male screw. The ring-shaped filter ring has an inner circumferential projection inserted into between the filter ring retainer and the OIS base frame, and is disposed on the outer circumferential side of the filter ring retainer and the OIS base frame.

Abstract: A display device includes a window panel over a display panel. The window panel includes a display area to transmit an image generated by the display panel and a non-display area adjacent the display area. The window panel includes a first light-shielding printed layer and first to third decor printed layers. The first light-shielding printed layer is in the non-display area. The first decor printed layer is in the non-display area and covers a side surface of the first light-shielding printed layer and at least a portion of an upper surface of the first light-shielding printed layer. The second decor printed layer is on the first light-shielding printed layer and the first decor printed layer. The second light-shielding printed layer is on the first light-shielding printed layer and the second decor printed layer.

Abstract: A parallel detecting optical coherence tomography (OCT) setup and method, in which the light paths of the illumination of the sample and of the detection of the backscattered light do not use the same apertures. The separation of illumination and detection apertures filters these disturbing reflexes from the backscattered light of the sample and significantly increases image quality.

Abstract: A virtual-reality or augmented-reality viewer (1) for a mobile electronic device (2), the viewer (1) including a central body (3), a left lens (4) and a right lens (4) arranged in the central body (3), a left side body (5) connected to the central body (3), a right side body (5) connected to the central body (3), and a tension mechanism (6) which biases the left and right side bodies (5) towards each other. In a first viewer state, a left portion of the central body (3) is accommodated in the left side body (5) and a right portion of the central body (3) is accommodated in the right side body (5). In a second viewer state, the left portion of the central body (3) is not accommodated in the left side body (5) and the right portion of the central body (3) is not accommodated in the right side body (5), so that the left and right lenses (4) are not covered by the left or right side body (5).

Abstract: A method for determining wave-front aberration data of a to-be-tested optical system comprising the steps of: a) providing a wave-front sensing image of light received from the tested optical system; b) providing a model representative of the optical system with at least an optical parameter representative of said model; and c) optimizing a set of wave-front coefficient data and said at least optical parameter of said model according to a merit function calculating the merit function comprises the steps of generating a wave-front sensing modeled image of light received from said model by the at least optical parameter and the set of wave-front coefficient data, and calculating a criteria based on shape parameter data of the wave-front sensing image and shape parameter data of the wave-front sensing modeled image, so as to obtain wave-front aberration data of the tested optical system.

Abstract: This invention provides a polarization conversion element that is highly resistant to the heat and light that result from increased brightness levels. In said polarization conversion element, inorganic half-wave plates provided selectively on the output surface of a polarizing beam-splitter array have obliquely deposited layers comprising a dielectric material and the side surfaces of said obliquely deposited layers are covered by protective films.

Abstract: The present disclosure provides a camera lens, including a first lens (focal length is f1), a second lens (focal length is f2), a third lens (focal length is f3), a fourth lens (focal length is f4) and a fifth lens (focal length is f5) which are successively arranged from an object side to an image side and which satisfy the following conditional expressions, 0.5<f1/f<0.7, ?2<f2/f<?0.5, 1.6<f3/f<2.0, ?2.1<f4/f<?1.45, ?1.5<f5/f<?1.2, in which, f is the focal length of the integral camera lens. Through reasonably optimizing surface type, allocating focal power and selecting optical material, the present disclosure designs a camera lens with a long focal length, which has the advantages of high sensitivity, low sensitivity, the chromatic aberration can be better calibrated, resulting in good optical performance.

Abstract: A lens module may include a first lens having positive refractive power, a second lens having refractive power, a third lens having positive refractive power, a fourth lens having refractive power, a fifth lens having refractive power, a sixth lens having refractive power, and a seventh lens having negative refractive power. An inflection point may be formed on an image-side surface of the sixth lens. A turning point may be formed on an image-side surface of the seventh lens. The first lens, the second lens, the third lens, the fourth lens, the fifth lens, the sixth lens and the seventh lens are disposed in a sequential order from the first lens to the seventh lens.

Abstract: Methods, systems, and apparatus, for optical depolarization. One optical depolarizer includes a light-combining module comprising a birefringent prism, wherein an optic axis of a first crystal of the birefringent prism forms a 90° angle with an optic axis of a second crystal of the birefringent prism; and a depolarization module, wherein the depolarization module is disposed at a light emitting end of the light-combining module, the depolarization module comprising a light splitting component and a light-combining component disposed at an emitting end of the light-splitting component, and a delayer disposed between the light-splitting component and the light-combining component, wherein the delayer is disposed on an emitting optical path of the light-splitting component.

Abstract: A fastening structure of a brittle-fracturable panel material includes a first fastening flange, a second fastening flange, and a light transmission window panel made of a brittle-fracturable panel material, wherein the light transmission window panel is nipped between the first fastening flange and the second fastening flange, and both fastening flanges are air-tightly fitted and fastened.

Abstract: The present disclosure relates to prismatic retroreflective articles that includes a security mark and to methods of making such articles.

Abstract: A photomanipulation device is described that includes multiple spatial light modulators (SLMs). By having more than one SLM, this device can simultaneously photomanipulate different areas with different wavelengths and/or it can rapidly switch between different areas with speeds faster than a single device is capable of. This device is particularly useful for photostimulation of neurons where simultaneity and precision timing is required.

Abstract: Provided is a zoom lens, comprising, in order from object side to image side: first positive, second negative and third positive lens units and a rear lens group including at least one lens unit, in which: at telephoto end as compared to wide angle end, an interval between first and second lens units is increased, and an interval between second and third lens units is reduced; an interval between adjacent lens units is changed during zooming; the first lens unit consists, in order from object side to image side, of a first positive lens sub-unit, and a second negative lens sub-unit over a widest air interval; and a focal length ft of zoom lens at telephoto end, a focal length f1a of first lens sub-unit, a lateral magnification ?1b of second lens sub-unit, and a lateral magnification ?2t of second lens unit at telephoto end are appropriately set.