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

Abstract: An interferometric modulating device is provided with a thermal expansion balancing layer on a side of the movable flexible layer opposite the movable reflector such that when temperature changes the distance between the movable reflector and the optical stack does not change significantly, thereby leading to stable color. Additionally, an interferometric modulating device is provided with a stiffening layer between the movable flexible layer and the movable reflector and at least one hollow void exists on the surface where the movable reflector and the stiffening layer contact each other so that the movable reflector is more rigid to bending, thereby reducing the temperature sensitivity of the movable reflector.

Abstract: Devices, methods, and systems comprising a MEMS device, for example, an interferometric modulator, that comprises a cavity in which a layer coats multiple surfaces. The layer is conformal or non-conformal. In some embodiments, the layer is formed by atomic layer deposition (ALD). Preferably, the layer comprises a dielectric material. In some embodiments, the MEMS device also exhibits improved characteristics, such as improved electrical insulation between moving electrodes, reduced stiction, and/or improved mechanical properties.

Abstract: This disclosure provides apparatus, systems and methods of fabricating force-sensitive switches. In some implementations, an array of force-sensitive switches and local capacitors of a combined sensor device may be used to connect the local capacitor into associated projected capacitive touch (PCT) detection circuitry. In some implementations, each capacitor may be formed with a thin dielectric layer to achieve a high capacitance increase when the force-sensitive switch is closed, e.g., by the pressing of a stylus or finger. In some implementations, the same PCT detection circuitry can be used to detect changes in mutual capacitance when touched with a finger (touch mode) and changes in sensel capacitance when the force-sensitive switch is depressed (stylus or fingerprint mode).

Abstract: This disclosure provides systems, methods and apparatus implementations of a display device with a cover glass apparatus that serves as a single or multi-touch sensor, as a handwriting (or note capture) input device, and in some configurations as a fingerprint sensor. Sensor functionality and resolution can be tailored to specific locations on the cover glass apparatus. In some such implementations, the area in which the fingerprint sensing elements are located may provide not only fingerprint detection, but also handwriting and touch functionality. In some other implementations, the fingerprint sensor may be segregated into a separate, high-resolution zone that only provides fingerprint functionality.

Abstract: Use of a compliant, elastomeric layer between upper and lower substrates of the combination sensor can increase the sensitivity to applied pressure or force from a stylus, while increasing the lateral resolution for a given sensel pitch. The elastomeric material may have an index of refraction that is substantially similar to that of the upper and lower substrates. The elastomeric material may include open regions for the inclusion of force-sensitive resistors. With careful selection of the elastomeric and FSR materials, the loss of transmissivity that can accompany air gaps can be minimized.

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: The present disclosure provides methods, systems, and apparatus for directing incident light toward central regions of interferometric modulator displays. In one aspect, a display includes an array of microlenses embedded in a substrate adjacent a first surface of the substrate. An array of light modulators can be disposed over the first surface of the substrate. A light modulator can be disposed over a corresponding microlens. The microlenses can converge or concentrate incident light onto central regions of the corresponding light modulators. The microlenses may include single-element lenses, compound lenses, and/or graded-index lenses. Various methods of manufacturing such displays are also disclosed.

Abstract: A composite display is disclosed. In some embodiments, a composite display comprises a paddle configured to sweep out an area and a plurality of pixel elements mounted on the paddle. Selectively activating one or more of the plurality of pixel elements while the paddle sweeps the area causes at least a portion of an image to be rendered. In some embodiments, a characteristic of at least one pixel element of the plurality of pixel elements that is associated with balancing luminance across at least a portion of the composite display associated with the paddle is based at least in part on a radial distance of the one pixel element from an axis of rotation of the paddle.

Abstract: Fabrication methods for combined sensor devices include substantially transparent substrates and materials to increase the optical performance of underlying displays. A substantially transparent elastomeric material may be disposed between the substantially transparent substrates. Some fabrication processes utilize flexible substrates for at least a portion of the sensor device, and lend themselves to roll-to-roll processing for low cost.

Abstract: This disclosure provides systems, methods and apparatus for a combined sensor device. In some implementations, a combined sensor device includes a wrap-around configuration wherein an upper flexible substrate has patterned conductive material on an extended portion to allow routing of signal lines, electrical ground, and power. One or more integrated circuits or passive components, which may include connecting sockets, may be mounted onto the flexible layer to reduce cost and complexity. Such implementations may eliminate a flex cable and may allow a bezel-less configuration.

Abstract: This disclosure provides systems, methods and apparatus for a combined sensor device. In some implementations, the combined sensor device may enable a single touchscreen to perform additional functions such as handwriting input and fingerprint recognition. In some implementations, these multiple features allow increased security through user authentication, and allow better capture of handwriting and a more interactive approach to user interfaces. A handheld mobile device such as a cell phone with the combined sensor device can enable an array of applications, such as using the mobile device as a gateway for user authentication to enable transactions and physical access; using the handwriting input function for signature recognition and transmittal for transaction applications; and/or using the handwriting input feature to automatically capture notes and other documents of students in an academic setting or employees in a corporate setting.

Abstract: A separate control system may be configured for a combined sensor device. Alternatively, at least part of the control system may be included in another device, such as a processor of a mobile device. Software for handwriting, touch and fingerprint detection may be included in the control system. Low, medium and high resolution may be obtained with a single combined sensor device by scanning a subset of the sensels, or by aggregating lines or columns. Power consumption may be reduced by aggregating sensor pixels (or rows or columns) electrically using the controller, so that they perform as a low power small array until higher resolution with a larger array is needed. Power consumption may be reduced by turning off portions or all of the sensor device, turning off parts of the control system, and/or employing first-level screening at a reduced frame rate.

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: Examples of methods of manufacturing a microelectromechanical system (MEMS) device can include forming a first reflective layer on a substrate, forming a sacrificial layer over the first reflective layer, removing a portion of the sacrificial layer to form an opening, and filling the opening with a dielectric material to form a post. Some methods further include forming a second reflective layer over the sacrificial layer, removing a portion of the second reflective layer and a portion of the post to form a hole, filling the hole with a conductive material to form an electrode, and removing the sacrificial layer.

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

Abstract: The present disclosure provides systems, methods, and apparatus to facilitate edge routing among a plurality of microelectromechanical devices arranged in a mosaic or array. In one aspect, the disclosed implementations modify the construction of a movable layer, such that portions of the movable layer, in addition to serving their original functions, also facilitate routing from a single edge of the device. In some implementations, portions of the movable layer are re-oriented to achieve edge routing, while in others, the orientation remains the same but electrical connections are altered.

Abstract: This disclosure provides systems, methods and apparatus, including reflective display elements that are illuminated using a light source that is situated behind the pixel elements. In one aspect, a back light guide is disposed behind the pixel elements and is configured to inject light through light-injection apertures between reflective pixel elements. The light travels through the light-injection apertures and into a front light guide. The front light guide comprises light turning features configured to turn the light propagating through the light-injection apertures so that the light is redirected onto the reflective pixel elements, thereby illuminating the reflective pixel elements.

Abstract: A microelectromechanical systems device having support structures formed of sacrificial material surrounded by a protective material. The microelectromechanical systems device includes a substrate having an electrode formed thereon. Another electrode is separated from the first electrode by a cavity and forms a movable layer, which is supported by support structures formed of a sacrificial material.

Abstract: An interferometric modulator (“IMOD”) display utilizes ambient light and incorporates touch sensing without reducing the amount of ambient light that reaches the MEMS modulators, and without introducing any optical distortion or loss of performance. Electrodes for touch sensing are located at a back glass of the inteferometric display, and are used in conjunction with electrodes whose primary function is to activate the pixels of the MEMS display, in order to sense a touch. The touch deflects the IMOD layers and is sensed through the various display layers at the rear of the display.