Abstract: A dual-mode light field camera or plenoptic camera is enabled to perform both 3D light field imaging and conventional high-resolution 2D imaging, depending on the selected mode. In particular, an active system is provided that enables the microlenses to be optically or effectively turned on or turned off, allowing the camera to selectively operate as a 2D imaging camera or a 3D light field camera.

Abstract: A micro-electromechanical reflector is described including an electrode substrate having a first surface and a second surface, which is opposite to the first surface, on whose first surface a carrier layer is situated, a plurality of electrode recesses, which are introduced under the carrier layer from the first surface into the electrode substrate, a plurality of second electrode recesses, which are introduced from the second surface into the electrode substrate, at least one torsion spring structure which is formed in the carrier layer over one of the first electrode recesses, a carrier substrate, which is attached to the second surface of the electrode substrate, and a reflector surface, which is situated on the carrier layer.

Abstract: A mobile terminal and controlling method thereof are disclosed, by which a holography user interface is provided.

Abstract: A solid-state image pickup apparatus including a substrate and a solid-state image pickup device. The substrate includes an opening portion. The solid-state image pickup device is mounted as a flip chip on a lower surface of the substrate on a circumference of the opening portion and receives and photo-electrically converts light that is taken in by a lens set on an upper surface of the substrate and enters from the opening portion. The circumference of the opening portion of the substrate is thinner than other portions of the substrate.

Abstract: A DMD having an array of micromirror pixels wherein each pixel comprises a right electrode on a first side of the pixel, a left electrode on a second side of the pixel adjacent the first side and a cantilevered beam supporting a mirror. The cantilever beam tilts on two axes of translation: pitch and roll. The mirror has a first landed position (on a first and second spring tip) over the right electrode and a second landed position (on the first and a third spring tip) over the left electrode such that the first landed position and the second landed positions are 90° apart. In transitioning from the first landed position to the second landed position, the mirror maintains contact with the first spring tip while rolling from the second spring tip to the third spring tip.

Abstract: Disclosed herein is a display device including a reflection type image display portion having a sheet-like anisotropic scattering member. In an area, in an in-plane direction, of the anisotropic scattering member, a low-refractive index area and a high-refractive index area are disposed in a mixture style. The anisotropic scattering member is disposed in such a way that a light is scattered when an outside light is made incident from a surface side on which a degree of a change in a refractive index in a vicinity of a boundary between the low-refractive index area and the high-refractive index area is relatively large, and is emitted from a surface side on which the degree of the change in the refractive index in the vicinity of the boundary between the low-refractive index area and the high-refractive index area is relatively small.

Abstract: A method of determining a reference calibration setting for an adaptive optics system comprising a detecting device for detecting light from an object; and at least one controllable wavefront modifying device arranged such that light from the object passes via the wavefront modifying device to the detecting device. The method comprises: arranging a light-source between the object and the wavefront modifying device to provide a reference light beam to the detecting device; for each of a plurality of orthogonal wavefront modes: controlling the wavefront modifying device to vary a magnitude of the orthogonal wavefront mode; acquiring a series of readings of the detecting device, each reading corresponding to one of the magnitude; determining a quality metric value for each reading, resulting in a series of quality metric values; and determining a reference parameter set for the wavefront modifying device corresponding to an optimum quality metric value.

Abstract: An electrowetting display device includes a greyscale picture element layer having at least one first picture element having a first fluid configurable to provide a greyscale display state, and a color picture element layer having at least one second picture element having a second fluid configurable to provide a color display state.

Abstract: A display panel includes: a substrate constituted by an active matrix substrate; a substrate opposite the substrate; and a light modulation layer interposed between the substrates. The change in the magnitude or the frequency of the voltage applied between a pixel electrode and a common electrode rotates a shape-anisometric member in the light modulation layer, and the pixel electrode extends over a scan signal line over an insulating layer.

Abstract: A color deviation balance thin film, a side-type backlight module and a liquid crystal display device. The color deviation balance thin film is applied to the side-type backlight module and the thickness of the color deviation balance thin film is gradually reduced along the backlight irradiation direction. The color deviation balance thin film is arranged in the side-type backlight module and the side-type backlight module with the color deviation balance thin film is arranged in the liquid crystal display device. When the side-type backlight module with the color deviation balance thin film is applied to the liquid crystal display device, the intensity difference of light at different positions along the backlight irradiation direction can be reduced, and the problem of the color deviation generated in the display picture can be effectively improved.

Abstract: After a TEOS oxide film is formed on the surface of a semiconductor device, a PSG film and an SiN film, which have air permeability, are formed on the surface of the TEOS oxide film. Thereafter, a Poly-Si film is formed thereon. A sacrifice layer is removed by a gaseous HF that passes through the PSG film, the SiN film, and the Poly-Si film, and then, the uppermost layer is covered with a Poly-Si/SiC film. A chip scale package having a thin-film hollow-seal structure can be realized on the semiconductor element.

Abstract: Integrated MEMS switches, design structures and methods of fabricating such switches are provided. The method includes forming at least one tab of sacrificial material on a side of a switching device which is embedded in the sacrificial material. The method further includes stripping the sacrificial material through at least one opening formed on the at least one tab which is on the side of the switching device, and sealing the at least one opening with a capping material.

Abstract: An electrowetting display apparatus includes a first base substrate, a second base substrate which faces the first base substrate, a first electrode on the first base substrate, and a second electrode on the second base substrate, where the second electrode faces the first electrode. A barrier wall is on the first electrode, where the barrier wall defines a storage area. A surface of the first electrode and the barrier wall is overlapped by a barrier layer. In addition, a water-repellent layer is on the barrier layer which is in the storage area. First and second fluids are in the storage area, the first fluid is separate from the second fluid, and the first fluid or the second fluid has a polarity.

Abstract: According to embodiments, an optically-actuated mechanical device comprises at least one deformable section formed of: an element including an intrinsic stress differential or gradient, the stress tending to urge deformation of one portion relative to another portion; and an optically-sensitive material which is configured to (i) initially prevent deformation of the device, and (ii) upon sufficient heating by absorbing optical energy allows the element to deform. The devices may be incorporated into various devices and apparatuses for select, non-contact actuation using only optical energy, for example, via light, from one or more lasers. Methods for fabricating and actuating such devices are also disclosed.

Abstract: An electronic device may include a processor, a memory coupled to the processor, and a touch-enabled display coupled to the processor. The processor may be for generating a lattice of nodes of a circular packing being based upon a connected transformation of a square circular packing. The connected transformation may preserve adjacency between pairs of adjacent circles of the square circular packing after a transformation. The processor may also be for displaying a lattice keyboard on the touch-enabled display. The lattice keyboard may include keys, each of the key being associated with an input value and being selectable based on user touches provided to the touch enabled display. The keys may be arranged in a lattice pattern such that the center of each key is placed in the position of a respective node of the lattice.

Abstract: Described herein are multi-segmented nanowires, nanosheets and nanobelts, and devices and methods using them for the generation of multicolor and white light.

Abstract: The invention relates to a fluidic, in particular an electrofluidic display element, comprising at least one pixel chamber (1) which is in fluid communication with at least one reservoir volume (2), wherein an electrically conducting and/or polar liquid (3) can be reciprocated between the pixel chamber (1) and the reservoir volume (2), wherein the pixel chamber (1) has a height (H) and a pixel width (B) and the reservoir volume (2) has a reservoir width (D) and a length (L), characterized in that the width (D) of the reservoir volume (2) is insignificantly greater than or equal to the height (H) of the pixel chamber (1).

Abstract: This disclosure provides novel latching circuits, and pixel circuits and display devices that include such latching circuits. The latches herein include a switch positioned on an inverter coupling interconnect which couples two cross-coupled inverters of the latch. The switch is configured to control a passage of a current between the first and second inverters. By switching the switch OFF at a time a data voltage is transferred to the inverters, any leak current between the inverters can be interrupted. As a result, a malfunctioning of the data latch is prevented.

Abstract: An electrowetting display device has first and second fluids which are immiscible with each other and a first and a second support plate, a surface of the second support plate being located for being adjoined by the second fluid. An electrode which contacts the second fluid forms part of a protrusion and is separated from the surface of the second support plate.

Abstract: An autofocus lens system includes no conventional moving parts and has excellent speed and low power consumption. The system includes a small electronically-controlled focusing-module lens. The focusing-module lens includes two adjustable polymeric surfaces (e.g., two adjustable-surface lenses in a back-to-back configuration). The curvature of the surfaces can be adjusted to change focus. The performance of the autofocus lens system is extended by adding a conventional first and second lens, or lens group, on either side of the focusing-module lens. What results is an autofocus lens system with excellent near field and far field performance.

Abstract: A tunable photonic crystal color filter and a color image display apparatus including the same. A tunable photonic crystal color filter includes a first electrode, a second electrode on the first electrode, and a medium disposed between the first electrode and the second electrode. The medium includes charged nanoparticles having a lattice structure in the medium. The first electrode and the second electrode are formed of a material having a difference between an oxidative over-potential and a reductive over-potential.

Abstract: Provided is a spatial light modulation element comprising a substrate; a flat portion that is movable relative to the substrate; a flat board attached to the flat portion; and a dielectric film that is formed on a surface of the flat board opposite the surface on which the flat portion is attached, and reflects incident light. In the spatial light modulation element the dielectric film may include two or more types of dielectric layers that are repeatedly layered in an alternating manner, such that adjacent layers have different refractive indexes from each other. Furthermore, the dielectric film may be formed by alternately layering an Al2O3 film and a SiO2 film.

Abstract: An electro-wetting display panel including an active device array substrate, a dielectric layer, a rib structure, an opposite substrate, a first fluid and a second fluid is provided. The active device array substrate includes a first substrate and a plurality of pixel structures. Each pixel structure includes a shielding electrode connected to a common potential, an active device located between the shielding electrode and the first substrate, and a pixel electrode electrically connected to the active device. The dielectric layer covers the pixel structures. The rib structure is disposed on the active device array substrate and has openings. The active device and the pixel electrode of each pixel structure are located within one of the openings. The first fluid is configured between the dielectric layer and the opposite substrate. The second fluid is configured between the dielectric layer and the first fluid.

Abstract: This disclosure provides systems, methods and apparatus for a multi-state shutter assembly. The multi-state shutter assembly can be used in an electronic display. The shutter assembly can include a movable light obstructing component. The shutter assembly also can include first and second actuators configured to move the light obstructing component between three states, including a fully light obstructive state, a substantially transmissive state, and a partially transmissive state. At least one of the three states is a neutral state in which both the first and second actuators are in an unactuated state. The shutter assembly also can include a controller configured to control the first and second actuator to selectively move the light obstructing component into each of the three states.

Abstract: A radiation emitting element comprising a radiation transmissive element having a first refractive index, a first surface, a second, opposite surface, a radiation emitter adapted to emit radiation of a predetermined wavelength into the radiation transmissive element, and a plurality of radiation controlling elements, wherein each radiation controlling element comprises: a first liquid having a second refractive index, a second fluid having a third refractive index being lower than the second refractive index, the second refractive index being closer to the first refractive index than the third refractive index, means for altering a shape of the first liquid between two modes wherein: • in a first mode, the first liquid being in contact with the first surface at a first surface part, and an interface between the first liquid and the second fluid, at the first surface part, is not parallel to the first surface part and • in a second mode, a surface of the second fluid, at the first surface part, is at least sub

Abstract: An electronic device module includes a first substrate having a first wiring layer and a first alignment mark, the first alignment mark being transparent in a visible region of the electromagnetic spectrum, and a second substrate facing a part of the first substrate and having a second wiring layer and a second alignment mark facing the first alignment mark.

Abstract: A memory cell and a method of manufacturing a memory cell are provided. The memory cell includes a substrate; at least one first electrode disposed above the substrate; at least one second electrode disposed above the at least one first electrode; a moveable electrode disposed between the at least one first electrode and the at least one second electrode; wherein the moveable electrode is configured to move between the at least one first electrode and the at least one second electrode; wherein the moveable electrode comprises metal.

Abstract: This disclosure provides systems, methods and apparatus for a laminated film enclosing an array of microelectromechanical systems (MEMS) structures. In one aspect, a MEMS apparatus includes a substrate having a device region and an edge region surrounding the device region and an array of MEMS structures on the substrate at the device region. A protective layer is disposed over the array of MEMS structures. A laminated film is disposed over the protective layer and in contact with the substrate to form a seal at the edge region, where the laminated film forms a cavity between the substrate and the laminated film at the device region. The laminated film includes a moisture barrier layer facing away from the array of MEMS structures, and a desiccant layer facing toward the array of MEMS structures.

Abstract: MEMS devices and methods of fabrication thereof are described. In one embodiment, the MEMS device includes a bottom alloy layer disposed over a substrate. An inner material layer is disposed on the bottom alloy layer, and a top alloy layer is disposed on the inner material layer, the top and bottom alloy layers including an alloy of at least two metals, wherein the inner material layer includes the alloy and nitrogen. The top alloy layer, the inner material layer, and the bottom alloy layer form a MEMS feature.

Abstract: The disclosure of the present invention relates to an electrowetting array substrate and a display device. The electrowetting array substrate comprises a plurality of pixel units. Each pixel unit comprises a common electrode layer, a pixel electrode layer, a hydrophobic dielectric layer provided between the two electrode layers, a non-polar liquid layer spreading on the hydrophobic dielectric layer, and an aqueous electrolyte layer provided between the non-polar liquid layer and the common electrode layer. a surface of the hydrophobic dielectric layer, on which the non-polar liquid layer spreads, is provided with a groove, and the pixel electrode layer is provided with a through hole the position of which corresponds to that of the groove. With such structure, the spread-contract path of the non-polar liquid can be shortened and thus the response rate can be improved. Furthermore, the non-polar liquid can be confined within the pixel unit.

Abstract: An electrowetting display device comprising at least one picture element including a first fluid and a second fluid immiscible with the first fluid. A protrusion arranged through the second fluid and in contact with the first fluid provides a preferential initiation of motion of part of the first fluid in a first direction and a different part of the first fluid in a second direction.

Abstract: This disclosure provides systems, methods and apparatus for modulating light to form an image on a display, as well as methods manufacturing such apparatus. The display apparatus includes shutters having asymmetric light obstructing portions extending out from opposing sides of a shutter aperture along an axis of motion of the shutter. Actuators move the shutters laterally along the axis of motion to move the shutter between fully closed, partially open, and fully open states to modulate light, thereby forming an image.

Abstract: The invention relates to an improved apparatus and method for the design and manufacture of MEMS anchoring structures for light modulators in order to address the stresses of beams mounted on them.

Abstract: Techniques described herein generally relate to optical devices and methods of manufacturing optical devices. An example optical device includes a first substrate having a first optical element, a second substrate coupled to the first substrate, and cured resin. The first substrate has a first optical element. The second substrate has at least one supporting structure and a second optical element supported by the at least one supporting structure. The at least one supporting structure has at least one receptor. The cured resin is arranged in the at least one receptor of the at least one supporting structure effective to position the second optical element relative to the first optical element.

Abstract: A microscope includes: a light source configured to generate light for irradiating a specimen; a microscope main body which supports the light source and on which an accommodation unit that accommodates the specimen is placed; a plurality of optical units, each of which is detachably installed in the microscope main body, configured to arranged on an optical path of the light, and configured to change optical characteristics of the light incident thereon; an operation input unit that includes a plurality of input units configured to respectively receive inputs of drive signals for driving optical units to be controlled among the plurality of optical units; and a control unit configured to allocate optical units to be respectively driven with the drive signals by the plurality of input units according to the plurality of optical units installed in the microscope main body.

Abstract: An organic EL element has an anode and a cathode a light-emitting layer including an organic material provided between the anode and the cathode, a hole injection layer provided between the anode and the light-emitting layer, and a electron injection layer provided between the light-emitting layer and the cathode 7. The hole injection layer and the electron injection layer include metal atoms and sulphur atoms. The sulphur concentration in the hole injection layer and the electron injection layer is no less than 96 ppm and no more than 439 ppm in terms of numerical ratio of sulphur atoms to metal atoms in the hole injection layer.

Abstract: A system and method for an optical component that masks non-active portions of a display and provides an electrical path for one or more display circuits. In one embodiment an optical device includes a substrate, a plurality of optical elements on the substrate, each optical element having an optical characteristic which changes in response to a voltage applied to the optical element, and a light-absorbing, electrically-conductive optical mask disposed on the substrate and offset from the plurality of optical elements, the optical mask electrically coupled to one or more of the optical elements to provide electrical paths for applying voltages to the optical elements. In another embodiment, a method of providing an electrical signal to optical elements of a display comprises electrically coupling an electrically-conductive light-absorbing mask to one or more optical elements, and applying a voltage to the mask to activate the one or more optical elements.

Abstract: An electrowetting display device includes at least one picture element having a first support plate, a second support plate and a space between the first support plate and the second support plate. The first support plate includes a reflector for reflecting light and the second support plate includes a light diffuser.

Abstract: According to one embodiment, an electronic device includes a drive circuit on a semiconductor substrate, an insulating region including a first insulating part provided on the semiconductor substrate and formed of interlayer insulating films, and a second insulating part provided on the first insulating part, an element for a high-frequency provided on the insulating region and driven by the drive circuit, an interconnect including a first conductive part in the first insulating part, and a second conductive part in the second insulating part, and transmitting a drive signal from the drive circuit to the element, a first shield provided inside the insulating region and below the element, and a second shield provided inside the insulating region and below the second conductive part.

Abstract: This disclosure provides systems, methods, and apparatus for treating a self-assembled monolayer coating on a dielectric layer to improve epoxy adhesion to the self-assembled monolayer coating. In implementations of the methods, a dielectric layer on a surface of a substrate is provided. A self-assembled monolayer coating is formed on the dielectric layer. A seal region of the self-assembled monolayer coating is selectively treated. A component is bonded to the seal region of the self-assembled monolayer coating with an epoxy. Implementations of the methods may be used to encapsulate an electromechanical systems device on the substrate with a cover using an epoxy.

Abstract: A display device comprises a substrate which carries an array of pixels. Each pixel comprises an array of apertures in the substrate, each aperture of the array having a maximum opening dimension less than the wavelength of the light to be transmitted through the aperture. The effective dielectric constant of the aperture and/or the dielectric constant of the substrate is varied, thereby to vary the light transmission characteristics of the pixel between transmission of at least one frequency in the visible spectrum and transmission of substantially no frequency in the visible spectrum.

Abstract: An organic light-emitting display apparatus and a method of manufacturing the same are provided. The organic light-emitting display apparatus includes a substrate, an organic light-emitting device on the substrate, an encapsulation layer covering the organic light-emitting device, and a low adhesive layer covering the encapsulation layer.

Abstract: This disclosure provides systems, methods, and apparatus for display device including a dielectric stack positioned between a first electrically conductive layer and a second movable electrically conductive layer. In one aspect, the dielectric stack includes alternating dielectric layers of high and low indices of refraction. By controlling the refractive indices and thicknesses of layers within the dielectric stack, the display device's states of light reflection may be reversed, such that light is reflected when the movable layer is positioned in proximity to the first electrically conductive layer.

Abstract: A method and apparatus for imaging a radiation-sensitive substrate, wherein a programmable template is projected onto the radiation-sensitive substrate using coherent radiation having a wavelength at which the substrate is radiation sensitive. An overall image of the programmable template having an image grid is displaced simultaneously by an acoustic-optical or electro-optical deflection unit such that multiple projections impinge on the substrate at different positions such that a fine partial grid is created in the image grid on the substrate.

Abstract: A novel method of modulating the motion or displacement of function units in MEMS (micro-electro-mechanical-system) devices (or MEMS motion transducers) is described. This method generates small vertical displacement of one MEMS component (activation component) in the device and effectively translates that displacement into the displacement of another MEMS component (function unit) in the same device in an in-plan direction that is perpendicular to the direction of the vertical displacement of activation component. The activation component has a large surface area of electrostatic interaction with its interacting electrode, capable of generating large activation force at small voltages. Therefore this method makes it effective to modulate the motion or displacement of the function unit of MEMS motion transducers in an in-plan direction at low voltages. Specific designs of MEMS motion transducers employing this method are disclosed.

Abstract: The disclosure provides an electro-wetting element, including: a first substrate and a second substrate, wherein the first substrate and the second substrate are disposed oppositely; a first electrode formed on the first substrate; a photoreactive layer formed on the first electrode, wherein the photoreactive layer includes a reversible photoreactive material; a second electrode formed on the first substrate or the second substrate; and a polar fluid and a non-polar fluid disposed between the first substrate and the second substrate.

Abstract: An electro-wetting display apparatus includes a first base substrate, a plurality of first electrodes on the first base substrate, an insulating layer which overlaps the first electrodes, a pixel wall on the insulating layer, where the pixel wall partitions a plurality of pixels respectively corresponding to the plurality of first electrodes, a second base substrate which face the first base substrate, a second electrode on the second base substrate and including a plurality of openings, and a fluid between the first base substrate and the second base substrate and in the plurality of pixels. The movement of the fluid in the plurality of pixels is controlled by voltages respectively applied to the first electrodes and the second electrode.

Abstract: In one embodiment, the electrowetting device includes a first medium; a second medium that is not mixed with the first medium and has a refractive index different from a refractive index of the first medium; an upper electrode that adjusts an angle of a boundary surface between the first medium and the second medium; and a barrier wall that has a side surface surrounding the first and second mediums, allows the upper electrode to be disposed on a portion of the side surface, and has irregular widths.

Abstract: A flexible liquid crystal display and a flexible fluid display are provided. The flexible liquid crystal display includes a first module, a second module, at least two supporting structures and a liquid crystal layer. The second module is disposed correspondingly to the first module. The supporting structures are separately disposed between the first module and the second module and used for abutting the first module and the second module, so that a space between the first module and the second module is divided into a flexible area and two non-flexible areas. The flexible area is located between the two non-flexible areas. The liquid crystal layer is disposed in the flexible area and the two non-flexible areas.

Abstract: A substrate for an electrowetting display device including a pixel electrode, a partition wall pattern and a water-repellent pattern. The pixel electrode is formed on a base substrate. The partition wall pattern is disposed along an edge of the pixel electrode to expose the pixel electrode. The water-repellent pattern is disposed at a space formed by the pixel electrode and the partition wall pattern to be extended along a lower portion of side surfaces of the partition wall pattern from an area on which the pixel electrode is formed. The water-repellent pattern exposes an upper portion of the side surfaces and an upper surface of the partition wall pattern. Thus, a manufacturing reliability of a substrate for an electrowetting display device is improved to prevent a display quality from being reduced.