Abstract: Illumination devices and methods of making same are disclosed. In one embodiment, a display device includes a light modulating array and a light guide configured to receive light into at least one edge of the light guide. The light guide can be characterized by a first refractive index. The display device can also include a light turning layer disposed such that the light guide is at least partially between the turning layer and the array. The turning layer can comprise an inorganic material characterized by a second refractive index that is substantially the same as the first refractive index.

Abstract: Improvements in an interferometric modulator that has a cavity defined by two walls.

Abstract: This disclosure provides systems, methods and apparatus for masked reflective structures which can be integrated into display devices. In one aspect, masks and etch leading layers can be used to control the etching of a stack of layers to form masked reflective structures having a desired profile. In particular, tapered edges at a particular angle can be formed, and the resulting structures used in a roll-to-roll process to fabricate a device component.

Abstract: This disclosure provides systems, methods and apparatus, including computer programs encoded on computer storage media, for sensing touch and/or gestures in the near-field area overlying a light-guiding layer within a device or other optical sensing system. In one aspect, modulated infrared light is emitted into the overlying area, and the light reflected by objects within the overlying area is redirected through the light-guiding layer to infrared sensors. In one aspect, a masking structure can be located between the light-guiding layer and the infrared sensors. In some aspects, probability mapping or backtracing can be used to estimate the locations of objects within the overlying area.

Abstract: This disclosure provides implementations of multi-gate transistors, structures, devices, apparatus, systems, and related processes. In one aspect, a device includes a thin-film semiconducting layer arranged over a substrate. A drain and source are coupled to the semiconducting layer. The device also includes first, second and third gates all arranged adjacent the semiconducting layer and configured to receive first, second, and third control signals, respectively. Dielectric layers insulate the gates from the semiconducting layer and from one another. In a first mode, the first, second, and third gates are configured such that charge is stored in a potential well in a region of the semiconducting layer adjacent the second gate. In a second mode, the first, second and third gate electrodes are configured such that the stored charge is transferred through the region of the semiconducting layer adjacent the third gate electrode and through the source to a load.

Abstract: This disclosure provides systems, methods, and apparatus for an electromechanical systems (EMS) device with one or more protrusions connected to a surface of the EMS device. In one aspect, the EMS device includes a substrate, a stationary electrode over the substrate, and a movable electrode over the stationary electrode. The movable electrode is configured to move to three or more positions across a gap by electrostatic actuation between the movable electrode and the stationary electrode. When the protrusions contact any surface of the EMS device at one of the positions across the gap, the protrusions change the stiffness of the EMS device. At least one of the surfaces in contact with the one or more protrusions is non-rigid. In some implementations, the protrusions have a height greater than about 20 nm.

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: Electromechanical systems dilation mode resonator (DMR) structures are disclosed. The DMR includes a first electrode layer, a second electrode layer, and a piezoelectric layer formed of a piezoelectric material. The piezoelectric layer has dimensions including a lateral distance (D), in a plane of an X axis and a Y axis perpendicular to the X axis, and a thickness (T), along a Z axis perpendicular to the X axis and the Y axis. A numerical ratio of the thickness and the lateral distance, T/D, is configured to provide a mode of vibration of the piezoelectric layer with displacement along the Z axis and along the plane of the X axis and the Y axis responsive to a signal provided to one or more of the electrodes. Ladder filter circuits can be constructed with DMRs as series and/or shunt elements, and the resonators can have spiral configurations.

Abstract: A system and method for manufacturing a display device having an electrically connected front plate and back plate are disclosed. In one embodiment, the method comprises printing conductive raised contours onto a non-conductive back plate, aligning the back plate with a non-conductive front plate such that the raised contours align with conductive routings on the front plate to electrically connect the raised contours and the routings, and sealing the back plate and the front plate.

Abstract: This disclosure provides systems, methods and apparatus relating to electromechanical display devices. In one aspect, a multi-stage interferometric modulator (IMOD) can include a movable reflector that can be moved to different positions to produce different reflected colors. The IMOD can include deformable elements that are coupled to a back side of the movable reflector and provide support to the movable reflector. The deformable elements can provide a restoring force that biases the movable reflector to a resting position. The IMOD can include one or more restoring force modifiers that are configured to increase the restoring force when engaged. The restoring force modifiers can be between the movable reflector and the deformable elements such that the deformable elements contact the restoring force modifiers when the movable reflector is displaced to a contacting position.

Abstract: A light guide may include a light guide core, light-extracting elements and cladding layers having lower refractive indices than that of the light guide core. The light guide may be a component of a front light system for a display. The display may be a reflective display, such as a reflective liquid crystal display (LCD). One cladding layer may include color filters for the display and may be disposed between the light guide and the display. The front light system may include a light source system capable of providing light (which may be polarized) to the light guide. The light-extracting elements may be capable of extracting light from the light guide and providing extracted light to the display, via the color filters. The light-extracting elements may include electrodes, such as electrodes for a touch sensor system.

Abstract: Embodiments of an interferometric modulator are disclosed having various enhancements and features including a conductive bus. In certain embodiments, the interferometric modulator has a first conductive layer suspended over a second electrode layer. In certain embodiments, a second conductive layer is provided over the first conductive layer. One of the first and/or second conductive buses may further connect to the first electrode layer and/or the second electrode layer. Other disclosed features can be incorporated into embodiments of the interferometric modulator to improve response time, power consumption, and image resolution.

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: This disclosure provides implementations of electromechanical systems resonator structures, devices, apparatus, systems, and related processes. In one aspect, a contour mode resonator device includes a first conductive layer with a plurality of first layer electrodes including a first electrode at which a first input signal can be provided and a second electrode at which a first output signal can be provided. A second conductive layer includes a plurality of second layer electrodes including a first electrode proximate the first electrode of the first conductive layer and a second electrode proximate the second electrode of the first conductive layer. A second signal can be provided at the first electrode or the second electrode of the second conductive layer to cooperate with the first input signal or the first output signal to define a differential signal. A piezoelectric layer is disposed between the first conductive layer and the second conductive layer.

Abstract: This disclosure provides systems, methods and apparatus relating to implementations of an electrically controlled light conditioning sheet. In one aspect, the electrically controlled light conditioning sheet includes a planar electrode having a first conductor and a second conductor and a transmissive elastic layer. The transmissive elastic layer is configured to deform in response to a potential difference applied between the first and the second conductor and produce regions of optical refractive power. The angular spread and/or the radiation pattern of an incoming beam of light incident on the electrically controlled light conditioning sheet is altered by the action of the regions of optical refractive power produced by the applied potential difference.

Abstract: This disclosure provides systems, methods and apparatus for an electromechanical systems reflective display device. In one aspect, an electromechanical systems display device includes a reflective layer and an absorber layer. The absorber layer is spaced apart from the reflective layer to define a cavity between the absorber layer and the reflective layer. The absorber layer is capable of transmitting light into the cavity, absorbing light, and reflecting light, and includes a metal layer. A plurality of matching layers are on a surface of the absorber layer facing away from the cavity, the plurality of matching layers including a first matching layer disposed on the absorber layer and a second matching layer disposed on the first matching layer.

Abstract: A display apparatus may include a multi-state IMOD, such as an analog IMOD (AIMOD), a 3-state IMOD (such as having a white state, a black state and one colored state) or a 5-state IMOD (such as having a white state, a black state and three colored states). The multi-state IMOD may include a movable reflective layer and an absorber stack. The absorber stack may include a first absorber layer having a first absorption coefficient and a first absorption peak at a first wavelength, a second absorber layer having a second absorption coefficient and a second absorption peak at a second wavelength, and a third absorber layer having a third absorption coefficient and a third absorption peak at a third wavelength. The first, second and third absorption layers may have absorption levels that drop to nearly zero at the center of each neighboring absorber layer's absorption peak.

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: This disclosure provides systems, methods and apparatus for diffusing light in a display device, such as a reflective display device. In one aspect, the display can include an array of display elements and an optical diffuser forward of the array. The diffuser can include an optically transmissive filler material and a plurality of spaced-apart protrusions extending into the filler material. The protrusions can have varying heights. In some portions of the diffuser, the protrusions may be formed of optically transmissive material, to provide diffusion. In some other portions, the protrusions may be formed of light absorbing material to form a black mask in those sections.

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.