Abstract: This document describes systems and techniques directed at compensating for voltage losses in organic light-emitting diode (OLED) displays. In aspects, a computing device having an OLED display and a luminance manager is configured to receive an indication of a luminance that is, or is intended to be, displayed by pixels of the OLED display. Responsive to and based on the received indication of luminance and a voltage loss, the luminance manager determines a luminance modification for the pixels of the OLED display. Based on the determined luminance modification, the luminance manager modifies the luminance that is displayed or modifies the luminance that is intended to be displayed by the pixels of the OLED display effective to compensate for the voltage loss.

Abstract: In general, techniques are described for image modification for under-display sensors. A computing device comprising a display, one or more sensors positioned underneath the display, and one or more processors may be configured to perform various aspects of the techniques. The display may be configured to allow the one or more sensors to operate through the display. The one or more processors may be configured to determine an ambient light level, and modify, based on the ambient light level, an area of an image to obtain a modified image. The area of the image may correspond to pixels of the display positioned above the one or more sensors or correspond to pixels of the display that are not positioned above the one or more sensors. The one or more processors may then interface, with the display, to output the modified image.

Abstract: In general, techniques are described for image modification for under-display sensors. A computing device comprising a display, one or more sensors positioned underneath the display, and one or more processors may be configured to perform various aspects of the techniques. The display may be configured to allow the one or more sensors to operate through the display. The one or more processors may be configured to determine an ambient light level, and modify, based on the ambient light level, an area of an image to obtain a modified image. The area of the image may correspond to pixels of the display positioned above the one or more sensors or correspond to pixels of the display that are not positioned above the one or more sensors. The one or more processors may then interface, with the display, to output the modified image.

Abstract: A system includes a microcontroller configured to: (a) receive, from an application processor, data for display on an organic light emitting diode (OLED) display having one region with a first dynamic range and another region having a second dynamic range; and (b) arrange the data into columns. A gamma generator is electrically connected to the microcontroller and generates first and second gammas specific to the different regions. A column driver is configured to: (a) apply the first gamma to each column to be displayed in the corresponding region to generate a first output, and apply the second gamma to each column to be displayed in the second region to generate a second output; and (b) electrically transmit the first and second outputs to the corresponding regions.

Abstract: A system includes a microcontroller configured to: (a) receive, from an application processor, data for display on an organic light emitting diode (OLED) display having one region with a first dynamic range and another region having a second dynamic range; and (b) arrange the data into columns. A gamma generator is electrically connected to the microcontroller and generates first and second gammas specific to the different regions. A column driver is configured to: (a) apply the first gamma to each column to be displayed in the corresponding region to generate a first output, and apply the second gamma to each column to be displayed in the second region to generate a second output; and (b) electrically transmit the first and second outputs to the corresponding regions.

Abstract: A method and apparatus for adjusting transmittance for a display of an electronic device based on brightness produced by a backlighting source for the display includes measuring, at each location of a plurality of locations on the display, a brightness level produced by the backlighting source during operation of the electronic device, using a sensor at each location. The method also includes determining, based on the measured brightness levels, a plurality of transmittance values each specifying a transmittance for a different area of multiple areas of the display, and electronically setting transmittance for each area of the multiple areas of the display using the plurality of transmittance values. Additionally, a method for adjusting the backlighting source includes turning off lighting elements of the backlighting source for an unused portion of the display and reducing luminosities of lighting elements of the backlighting source for a used portion of the display.

Abstract: A dual-sided electrophoretic display (700) having a first region (701) and a second region (702) is provided. Each of the first region (701) and the second region (702) includes selectively operable members (703,704) that function as pixels for presenting images on the electrophoretic display (700). Each of the selectively operable members (703,704) is driven by a driver circuit (710) by way of corresponding thin film transistors and capacitors (742,742), which are opaque. As the selectively operable members (704) of the second region (702) are bigger than are the selectively operable members (703) of the first region (701), the aperture ratio of the selectively operable members (704) of the second region (702) is greater than in the first region (701) when viewed from the rear side (730). Thus, a contrast ratio of the second region (602), when viewed from the rear side (730) is sufficiently high that text, icons, and characters presented in the second region (602) are legibly visible on the rear side (730).

Abstract: A method and system evaluates user interfaces (UIs) for presentation on a display of a mobile communication device. A display controller, in response to detecting an initiation of a presentation of a specified UI on the display, determines a type of the display by evaluating power consumption behavior of the display associated with individually presenting each of multiple pre-defined UIs on the display. Based on the display type, the display controller identifies a specific display parameter associated with the display and which identifies relevant image characteristics of UIs that can be presented on the display. The display controller evaluates a display parameter value for the specified UI, compares the display parameter value with a threshold display parameter value, and provides a notification that indicates, based on a result of the comparison, whether the specified UI satisfies the power consumption specification and is recommended for presentation on the display.

Abstract: A display includes an encapsulation layer and a substrate. The substrate includes a chip on glass (COG) seat and a flexible printed circuit (FPC) connector seat. The COG seat and the FPC seats are positioned on different edges of the substrate. A cross-connection layer between the substrate layer and the encapsulation layer, the cross-connection layer including traces connected between the COG seat and the FPC seat. A device incorporating the display may take advantage of the symmetrical display to achieve new designs.

Abstract: A display device (301) includes a plurality of pixels (302,309,310,315,330,331,332) operable to emit or modulate light. Each pixel of the plurality of pixels comprising a plurality of subpixels (303,304,305,306,307,308,311,312,313,333,334,335). To create an asymmetrical spacing across the display module, every pixel can at least two subpixels spaced apart from each other by a predetermined distance (336), while one or more pixels, which form a subportion of the plurality of pixels, each comprise at least one subpixel spaced apart from at least one adjacent subpixel by another predetermined distance (337), where the other predefined spacing is greater than the predefined spacing.

Abstract: A self emission device (644) that emits light (526). The self emission device can include at least one light emission layer (104) encompassing an area, and generating light over such area in a distributed fashion. The self emission device also can include a first electrode (113) interfacing with a first side (116) of the light emission layer and a second electrode (114) interfacing with a second side (117) of the light emission layer. The first electrode and the second electrode can provide energy used by the light emission layer to illuminate. The self emission device can be a component of a display (100) comprising a reflective display panel (102).

Abstract: A self emission device (644) that emits light (526). The self emission device can include at least one light emission layer (104) encompassing an area, and generating light over such area in a distributed fashion. The self emission device also can include a first electrode (113) interfacing with a first side (116) of the light emission layer and a second electrode (114) interfacing with a second side (117) of the light emission layer. The first electrode and the second electrode can provide energy used by the light emission layer to illuminate. The self emission device can be a component of a display (100) comprising a reflective display panel (102).

Abstract: A dual-sided electrophoretic display (700) having a first region (701) and a second region (702) is provided. Each of the first region (701) and the second region (702) includes selectively operable members (703,704) that function as pixels for presenting images on the electrophoretic display (700). Each of the selectively operable members (703,704) is driven by a driver circuit (710) by way of corresponding thin film transistors and capacitors (742,742), which are opaque. As the selectively operable members (704) of the second region (702) are bigger than are the selectively operable members (703) of the first region (701), the aperture ratio of the selectively operable members (704) of the second region (702) is greater than in the first region (701) when viewed from the rear side (730). Thus, a contrast ratio of the second region (602), when viewed from the rear side (730) is sufficiently high that text, icons, and characters presented in the second region (602) are legibly visible on the rear side (730).

Abstract: A display comprising a display driver termination portion (106), a dot matrix region (402) and an icon region (403). The icon region located in-between the display driver termination area and the dot matrix area, wherein the dot matrix area has a resolution that is greater than the icon area.