A content item to be displayed via a display of an electronic device may be associated with a first set of grey values or a set of color values. The electronic device may generate, maintain, or at least have access to one or more mappings that map the set of color values and/or the first set of grey values to a second set of grey values. Based on the one or more mappings, the electronic device may convert a color value of the set of color values or a first grey value of the first set of grey values to a second grey value of the second set of grey values. The content item may then be displayed utilizing the second grey value.

The present invention proposes an AMOLED driving device. The AMOLED device includes an AMOLED driving circuit, a scan driving signal source, a data driving signal source, and a data driving signal source control module. The AMOLED driving circuit includes a first semiconductor controllable switch, a second semiconductor controllable switch, an energy storage capacitor, and an organic light emitting diode.

The present invention provides a driving circuit for driving a color display to display black-and-white/grayscale images and comprises a data conversion circuit and a driver. The data conversion circuit receives input data transmitted by a microprocessor. The format of the input data is a black-and-white/grayscale format. The data conversion circuit converts the input data for producing output data. The format of the output data is a color format. The driver receives the output data and drives the color display to display the black-and-white/grayscale image. The driving circuit will convert the input data transmitted by the microprocessor with limited transmission capability and produce color output data for driving the color display to display the black-and-white/grayscale image. Accordingly, by using the driving circuit according to the present invention, an electronic device with limited transmission capability can work with the color display to display black-and-white/grayscale images.

An electronic device, method, and computer readable medium for a functional mode aware resource management. The electronic device includes a memory and at least one processor. The at least one processor is coupled to the memory. The at least one processor is configured to identify when an amount of a system resource is below a minimum resource threshold. The at least one processor is also configured determine a functional mode of the electronic device. The at least one processor is further configured to identify one or more processes not corresponding to the functional mode that are running on the electronic device. The at least one processor is further configured to terminate at least one of the one or more processes not corresponding to the functional mode when the amount of the system resource is below the minimum resource threshold.

According to an aspect, a display device includes: a display panel that has a display area in which a plurality of pixels are arranged; a light source configured to illuminate the display area; a first control circuit configured to receive first signals corresponding to a first partial image to be displayed in a portion of the display area; and a second control circuit configured to receive second signals corresponding to a second partial image to be displayed in another portion of the display area. The light source has a plurality of light-emitting areas in each of which a light emission intensity is individually controllable. The first control circuit is configured to transmit lighting quantity information indicating the light emission intensity of each of the light-emitting areas to the second control circuit.

In one embodiment, a computing system may receive a target color and a propagated error for a pixel location. The system may determine an error-modified target color for the pixel location based on the received target color and the propagated error. The system may identify, based on a location of the error-modified target color in a three-dimensional color space, a subset of pre-determined colors in the three-dimensional color space. The error-modified target color may correspond to a weighted combination of the subset of pre-determined colors. The system may determine a pixel color for the pixel location based on the subset of pre-determined colors and respective weights associated with the subset of pre-determined colors. The system may determine, based on the pixel color, driving signals for light-emitting elements associated with the pixel location. The system may output the driving signals to control the light-emitting elements associated with the pixel location.

This application discloses a driving method and a driving apparatus of a display device. The driving method comprises: acquiring a target color system which is to-be-adjusted, acquiring color shift grayscales corresponding to a color shift generated by the target color system, acquiring original grayscales corresponding to the target color system in an input signal, deleting a portion of color shift grayscales in the original grayscales, obtaining mapping grayscales corresponding to the target color system, adopting a high-bit drive semiconductor element or a frame ratio control, and outputting a signal of the mapping grayscales corresponding to the target color system.

An image display system includes an array of pixel elements, column drivers, row drivers, a look up table memory, and a controller. Input video data including gradation information of an input image is received. According to rules of a look up table, the input video data is assigned to multiple groups, binary signals for respective groups are generated using the respective input video data assigned to each group, and an order of the binary signals within at least some groups is rearranged to form respective binary control signals without conflicting state changes. The controller transmits the binary control signals to the column drivers and transmits a select signal that selects the row drivers. Alternatively, the controller transmits the binary control signals to the row drivers and transmits a select signal that selects the column drivers. The select and binary control signals are in synchronization with a clock signal.

This document relates to head mounted display devices. One example can include a layer of individually controllable pixels that can be energized to emit light and a layer of lenses that are physically aligned over the pixels. The example can also include a layer of shutters interposed between the pixels and the lenses and configured to be independently transitioned between a transmissive state and an opaque state to limit paths of the emitted light that reach the layer of lenses.

A method of image processing, the method including performing linear processing of an input data signal encoded with a nonlinear function to generate a linear representation of the input data signal including linearized image data, and using an integrated circuit to generate a processed linear image by nonlinearly quantizing the linearized image data to generate nonlinear quantized data, generating a memory address based on the nonlinear quantized data, and accessing a lookup table based on the generated memory address.