A structured film comprises an optically transmissive surface including a plurality of walls, each wall being adjustable between a plurality of configurations including a default configuration. When attached to a display, the walls extend away from the display at different heights and surround a plurality of light emitters of the display. In a default configuration, the walls generate selected diffraction orders for each light emitter such that gaps between adjacent light emitters are at least partially covered. The film can be adjusted by varying a geometry of the walls in response to an electrical input. The brightness of a region of interest in an image to be formed on the display can be adjusted relative to a surrounding region by varying wall geometry, using contrast control, or a combination thereof. The optically transmissive surface comprises a solid membrane filled with a non-solid material having a specific index of refraction.

The disclosure provides a bistable display device and a driving circuit. The bistable display device includes a display panel and the above-described driving circuit, wherein the driving circuit includes a source driver, a first image buffer, a second image buffer, and a timing controller. The source driver is coupled to the display panel to drive the display panel according to a pixel signal. The timing controller is coupled to the first image buffer, the second image buffer, and the source driver. The timing controller alternately selects a first image signal temporarily stored in the first image buffer and a second image signal temporarily stored in the second image buffer as a current image signal and a previous image signal. The timing controller performs a look-up mechanism based on the current image signal and the previous image signal to generate the pixel signal.

A direct view light emitting diode (DV LED) display (296), includes (i) one or more DV LED modules (200) each containing at least one circuit board (300) having an array of surface mount device LEDs (100) defining a display surface (304), and (ii) a protective transparent polymeric film (302, 390) covering at least a portion of the display surface. The transparent polymeric film includes a polymer material layer (400), and an adhesive layer (402) laminated to the polymer material layer and directly attached to the display surface of the DV LED module. The transparent polymeric film may facilitate the use of touch screen technology with a DV LED display, and may be removable to allow repair or disassembly/reassembly of the DV LED display.

According to one embodiment, a color changing display includes a housing, a cover cooperatively coupled to the housing, a light panel, and a color display panel. The light panel and the color display panel are positioned between the housing and the cover. The light panel and the colored display panel are each selectively activated to operate in at least one of: a reflective mode, a transmissive mode, and a transflective mode.

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.

An image display apparatus of the present disclosure includes: a light modulator that performs light modulation on the basis of data of a bit plane for each grayscale bit; and a transfer controller that divides the data of the bit plane into data of a plurality of groups and transfers the data of the respective groups to the light modulator at shifted transfer timings, the shifted transfer timings being sequentially shifted only by a predetermined shift amount corresponding to a subframe period of a least significant grayscale bit multiplied by a predetermined integral.

Subject matter disclosed herein relates to arrangements and techniques that provide for controlling motion of an electrowetting oil within an electrowetting display device. An electrowetting display device comprises a substrate, an electrode on the substrate, a dielectric layer on a first portion of the electrode. The electrode extends along the substrate one of either entirely from a first end of a pixel area to a second end of the pixel area, or from the first end of the pixel area to the second end of the pixel area such that a portion of the substrate is an electrode free portion to thereby define a notch. A first fluid is disposed on a hydrophobic layer and a second fluid is disposed on the first fluid, the second fluid being immiscible with the first fluid. A dielectric constant of the dielectric layer is greater than a dielectric constant of the first fluid.

A display device (4) for an identifier (6a,b) of a seat (8a,b) of a vehicle (2) with a variable mounting location (10a,b) contains a display (12) along an extension direction (14), which can be attached to a carrier (16) of the vehicle (2) at the seat (8a,b) in the extension direction (14) along possible mounting locations (10a,b), and a control device (22) for displaying identifiers (6a,b) on the display (12) in different longitudinal positions (Pa,b), which are assigned to mounting locations (10a,b). A vehicle (2) having such a seat (8a,b) and a carrier (16) contains the display device (4), wherein the display (12) is attached to the carrier (16) in the surroundings (20) of the seat (8a,b) and extends in the extension direction (14) along possible mounting locations (10a,b) of the seat (8a,b).

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 display device may include a first transistor, a first electrode, a second electrode, a first intermediate layer, and a first changeable layer. The first electrode is electrically connected to the first transistor. The second electrode overlaps the first electrode. The first intermediate layer is positioned between the first electrode and the second electrode and may emit first light when the first electrode and the second electrode generate a first electric field. The first changeable layer, which overlaps the first electrode, may have a first transmittance value when the first electrode and the second electrode generate the first electric field, and may have a second transmittance value when the first electrode and the second electrode do not generate the first electric field. The second transmittance value is unequal to the first transmittance value.