A driver apparatus configured to drive an electronic paper display panel to perform a touch sensing operation is provided. The driver apparatus includes a scanner apparatus and a sensing apparatus. The scanner apparatus scans multiple sensing blocks of the electronic paper display panel to perform the touch sensing operation. Each sensing block includes one or more sensing devices. The sensing blocks are arranged in an array. The sensing apparatus is electrically connected to the scanner apparatus. The sensing apparatus controls the scanner apparatus to scan the sensing blocks. The sensing apparatus charges/discharges each sensing block according to a first voltage and a second voltage, so that a relaxation signal is generated. A pulse difference of the relaxation signal is changed by the touch object. The touch object is a conductor. A touch position of the touch object on the electronic paper display panel is determined according to a relaxation frequency of the relaxation signal of each sensing block.

A method, computer readable medium, and system are disclosed for generating mixed-primary data for display. The method includes the steps of receiving a source image that includes a plurality of pixels, dividing the source image into a plurality of blocks, analyzing the source image based on an image decomposition algorithm, encoding chroma information and modulation information to generate a video signal, and transmitting the video signal to a mixed-primary display. The chroma information and modulation information correspond with two or more mixed-primary color components and are generated by the image decomposition algorithm to minimize error between a reproduced image and the source image. The two or more mixed-primary colors selected for each block of the source image are not limited to any particular set of colors and each mixed-primary color component may be selected from any color capable of being reproduced by the mixed-primary display.

A display device includes a display panel and at least one light modulation panel. The display panel includes a substrate and a plurality of micro light emitting semiconductors disposed on the substrate. The light modulation panel is disposed on a light emitting surface of the display panel and includes a light modulation unit. The light modulation panel is configured to change a transmittance of the light modulation unit according to a light modulation control signal.

A light-based output device may be used to display images, symbols, and other information for a user of a system such as a vehicle. A display may be formed from a display layer, a covering layer that covers the display layer, and components such as force and touch sensors and electronic shutters. Haptic feedback may be provided using actuators that are coupled to the covering layer. A movable button member may be used to press the covering layer outwardly within an opening, thereby creating a portion of the covering layer that protrudes from other portions of the covering layer. The button member may also be placed in a position in which the covering layer on the button member is flush with other portions of the covering layer. A touch sensor may be incorporated into the covering layer and may overlap a display and areas outside the display.

Embodiments of the present disclosure provide a MEMS light valve, a pixel array and a display apparatus. The MEMS light valve includes a first grating including first openings arranged in a matrix; a second grating, parallel to the first grating and including light emitting areas corresponding to the first openings, wherein the second grating is capable of moving with respect to the first grating along a shifting direction parallel to the first grating. Light emitting materials which emit lights having certain wavelengths by means of excitation by external lights are provided on the light emitting areas.

An information handling system may comprise a liquid crystal display having a plurality of pixels, an electrochromic material layer having a plurality of electrodes disposed between an interior surface of a chassis and a transistor-array layer, and a high reflection layer reflecting light emitted from an LED disposed between the electrochromic material layer and the transistor-array layer away from the interior surface of the chassis. A processor may execute code instructions of an electrochromic material regional backlight unit dimming control system to identify a low-intensity pixel region including a subset of the plurality of pixels associated within high dynamic ratio image data with a low intensity value, identify an electrode of the electrochromic material layer associated with the low-intensity pixel region; and pass a current through the electrode such that a portion of the electrochromic material becomes opaque to the light reflected from the high reflection layer.

A display device includes a base structure, a plurality of modules coupled to the base structure, where each of the modules include a plurality of actuator assemblies. Each of the actuator assemblies is individually controllable to move the actuator assemblies between a retracted state and a plurality of extended states. A controller is coupled to each of the modules and is programmed to control the actuator assemblies to move the actuator assemblies between the retracted state and the plurality of extended states.

The present disclosure discloses a mobile terminal and a battery cover of mobile terminal, the battery cover of mobile terminal includes a main control circuit, a power management circuit, a touch circuit and an e-Ink; wherein the main control circuit, the power management circuit and the touch circuit are connected to the e-Ink respectively; the main control circuit and the power management circuit are connected to the mobile terminal respectively; the main control circuit is connected to the touch circuit; the power management circuit is configured to supply power to the e-Ink; the touch circuit is configured to receive a screen changing operation of the e-Ink; and the main control circuit is configured to receive data from the touch circuit, communicate with the mobile terminal and display contents of communication on the e-Ink.

A method for secure updating of a static state display, the method comprising: sending (102) data from an updating device (400) to the static state display (300), wherein the data comprises a security key and update data pertaining to an update (302) to be displayed by the static state display (300); authenticating (104) the data sent by the updating device (400) at the static state display by comparing the security key with one or more reference security keys stored in a database accessible by the static state display (300); and upon successful authentication updating (106) the static state display (400) with the update (302). A system (200) comprising a static state display (300) and an updating device (400) is further provided.

Resources of a system for controlling optically switchable windows may be used for a personal computing unit. The window system resources may include (i) a display associated with an optically switchable window, (ii) one or more processors of one or more controllers on a window network connected to a plurality of optically switchable windows in a building, wherein the one or more controllers are configured to vary tint states of the plurality of optically switchable windows in the building, (iii) memory of one or more controllers on the window network connected to the plurality of optically switchable windows in the building, and/or (iv) at least a part of the window network.