Abstract: Disclosed herein are iMoD displays optimized by utilizing different materials for one or more different color subpixels. Such optimized displays have improved color gamut over displays where all subpixels are constructed with the same material. Also disclosed are methods for manufacturing such displays and methods for optimizing iMoD displays.

Abstract: An interferometric modulator array device with backlighting is disclosed. The interferometric modulator array device includes a plurality of interferometric modulator elements. Each of the interferometric modulator elements includes an optical cavity. The interferometric modulator array includes an optical aperture region, and at least one reflecting element is positioned so as to receive light passing through the optical aperture region and reflect at least a portion of the received light to the cavities of the interferometric modulator elements. The interferometric modulator elements may be separated from each other such that an optical aperture region is formed between adjacent interferometric modulator elements.

Abstract: In one embodiment of the invention, a display is provided and includes a plurality of interferometric display elements. The display further includes at least one diffuser. Optical properties of the diffuser are selected to reduce color shift of the display when viewed from at least one angle.

Abstract: A package structure and method of packaging for an interferometric modulator. A thin film material is deposited over an interferometric modulator and transparent substrate to encapsulate the interferometric modulator. A gap or cavity between the interferometric modulator and the thin film provides a space in which mechanical parts of the interferometric modulator may move. The gap is created by removal of a sacrificial layer that is deposited over the interferometric modulator.

Abstract: A MEMS-based display device is described, wherein an array of interferometric modulators are configured to reflect light through a transparent substrate. The transparent substrate is sealed to a backplate and the backplate may contain electronic circuitry fabricated on the backplane. The electronic circuitry is placed in electrical communication with the array of interferometric modulators and is configured to control the state of the array of interferometric modulators.

Abstract: One embodiment includes display comprising a light modulator configured to display a portion of an image such as a reflective light modulator, a light emitter configured to display the portion of the image and a circuit configured to selectively provide signals to at least one of the light modulator and the light emitter indicative of the portion of the image. In one such embodiment, an active matrix provides a simple, efficient drive for such devices. Other embodiments include methods of making and driving such devices.

Abstract: In various embodiments, an interferometric display device includes a plurality of structures that redirect light from an inactive area of the display to an active area of the display. Light incident on the structures that would normally continue towards an inactive area of the display is either reflected, refracted, or scattered towards an active area of the display including moveable and static reflective surfaces that form an optical cavity.

Abstract: A system and method for determining humidity based on determination of an offset voltage shift are disclosed. In one embodiment, a system for determining humidity comprises an electromechanical device comprising a first layer, a second layer, and a dielectric between the two layers, wherein the dielectric is spaced apart from at least one of the first and second layers in an unactuated state of the electromechanical device, and wherein the dielectric contacts both the first and second layers in an actuated state of the electromechanical device, a voltage source configured to apply, between the first and second layers, one or more voltages, and a processor configured to control the voltage source, to determine an offset voltage shift based on the applied voltages, and to determine information regarding humidity about the device based on the offset voltage shift.

Abstract: Electromechanical devices such as MEMS can be controlled by “drive schemes” comprising electrical signals applied to the display to cause selective actuation or release of the electromechanical devices. In some drive schemes, all pixels on a line are released during a phase when a release voltage is applied along the common line. In some invention embodiments, the release phase sets the common line voltage to the maximum segment drive voltage for a portion of the release phase and the minimum segment drive voltage for the remainder of the release phase. This ensures that all electromechanical devices have a resulting voltage of zero during a portion of the release phase sufficient to release the devices without regard to the segment line voltages. This scheme eliminates slow and no release problems and also eliminates the need for additional voltage transitions on the segment lines.

Abstract: Apparatus and methods of actuating MEMS display elements are disclosed. The disclosed embodiments can be incorporated into other drive schemes for MEMS display elements. In one embodiment, an apparatus for controlling a MEMS display element to display a frame of video data, said MEMS display element comprising a portion of an array of MEMS display elements, includes an array controller configured to assert a potential difference on said MEMS display element during a first portion of a frame display write process to place the MEMS display element in a first display state, and to assert a potential difference on said MEMS display element during a second portion of the frame display write process to place the MEMS display element in a second display state to display the frame of the video data, where the first display state is different from the second display state.

Abstract: Described herein is the use of a diffusion barrier layer between metallic layers in MEMS devices. The diffusion barrier layer prevents mixing of the two metals, which can alter desired physical characteristics and complicate processing. In one example, the diffusion barrier layer may be used as part of a movable reflective structure in interferometric modulators.

Abstract: Disclosed are methods, apparatus, and systems, including computer program products, implementing and using techniques for processing frames of video data sent across a display interface using a block-based encoding scheme and a tag ID. The disclosed techniques provide for optimization of the display interface situated between the graphics processor and the display controller of an electronic device. The disclosed techniques minimize the amount of signaling over the interface and reduce the power consumed at the interface. Accordingly, the battery life of some electronic devices can be extended. In one embodiment, the graphics processor is configured to receive frames of video data, where each frame includes one or more blocks of the video data. The graphics processor is configured to encode each block of video data, generate a tag ID associated with each encoded block of video data, and output each encoded block of video data and associated tag ID.

Abstract: Reflectors formed in front of a solar cell reduce loss from reflections from specular conductors formed in front of the photovoltaic material in the solar cell by reflecting light otherwise incident upon the conductors onto the photovoltaic material. In one embodiment, a solar cell includes a photovoltaic material having a front surface, a conductive bus line extending along a first direction, the conductive bus line being disposed over the front surface of the photovoltaic material, a primary reflector disposed on the bus line, the primary reflector comprising a first reflective surface obtusely angled relative to the front surface of the photovoltaic material to reflect light onto the photovoltaic material, and a first secondary reflector extending along the first direction, spaced apart from the conductive bus line, the first secondary reflector comprising at least one reflective surface to reflect a portion of light reflected from the primary reflector towards the photovoltaic material.

Abstract: Systems and methods for driving a display of MEMS devices are disclosed. In one embodiment, a display includes an array comprising a plurality of interferometric modulators, and a driving circuit coupled to said array, said driving circuit configured to provide actuation signals to drive said array based on a temperature of the display. In another embodiment, a method of driving an array having a plurality of interferometric modulators configured into a display is disclosed, where the method includes sensing the temperature at a predetermined location in display, communicating a signal based on the sensed temperature to a display driver, generating an actuation signal to drive said display based on the received signal, and providing the actuation signal to the array.

Abstract: A method of making an interferometric modulator element includes forming at least two posts, such as posts formed from spin-on glass, on a substrate. In alternate embodiments, the posts may be formed after certain layers of the modulator elements have been deposited on the substrate. An interferometric modulator element includes at least two spin-on glass support posts located on the substrate. In alternate embodiments, the support posts may be located over certain layers of the modulator element, rather than on the substrate. A method of making an interferometric modulator element includes forming a rigid cap over a support post. An interferometric modulator element includes support posts having rigid cap members.

Abstract: The color reflected by an interferometric modulator may vary as a function of the angle of view. A range of colors are thus viewable by rotating the interferometric modulator relative to an observer. By placing a textured layer between an observer and an interferometric modulator, a pattern which includes the range of colors may be viewed by the observer, and the range of colors may thus be viewable from a single viewing angle.

Abstract: Light in the visible spectrum is modulated using an array of modulation elements, and control circuitry connected to the array for controlling each of the modulation elements independently, each of the modulation elements having a surface which is caused to exhibit a predetermined impedance characteristic to particular frequencies of light. The amplitude of light delivered by each of the modulation elements is controlled independently by pulse code modulation. Each modulation element has a deformation portion having a flexible membrane held under tensile stress, and the control circuitry controls the deformation of the deformation portion. An optical portion may be formed on the flexible membrane which helps provides an optical response to movement of the deformation portion.

Abstract: Methods and systems for providing brightness control in an interferometric modulator (IMOD) display are provided. In one embodiment, an interferometric modulator display pixel is provided that includes a microelectromechanical systems (MEMS) interferometric modulator having an associated first color spectrum, and a color absorber located substantially in front of the interferometric modulator display pixel, in which the color absorber has an associated second color spectrum. The microelectromechanical systems (MEMS) interferometric modulator is operable to shift the first color spectrum relative to the second color spectrum to control a visual brightness of the interferometric modulator display pixel independent of a color of the interferometric modulator display pixel.

Abstract: Broad band white color can be achieved in MEMS display devices by incorporating a material having an extinction coefficient (k) below a threshold value for wavelength of light within an operative optical range of the interferometric modulator. One embodiment provides a method of making the MEMS display device comprising depositing said material over at least a portion of a transparent substrate, depositing a dielectric layer over the layer of material, forming a sacrificial layer over the dielectric, depositing an electrically conductive layer on the sacrificial layer, and forming a cavity by removing at least a portion of the sacrificial layer. The suitable material may comprise germanium, germanium alloy of various compositions, doped germanium or doped germanium-containing alloys, and may be deposited over the transparent substrate, incorporated within the transparent substrate or the dielectric layer.

Abstract: A voltage-controlled capacitor and methods for forming the same are described. A mechanical conductor membrane of the voltage-controlled capacitor is movable to and from a first position and a second position. An amount of capacitance can vary with the movement of the mechanical conductor membrane. A microelectromechanical systems (MEMS) voltage-controlled capacitor can be used in a variety of applications, such as, but not limited to, RF switches and RF attenuators.