A display driving apparatus is disclosed. The display driving apparatus includes a data processing unit, a first setting unit, a second setting unit, a mapping unit and a source driving unit. The data processing unit receives and processes an image data including data lines. The first setting unit generates a first setting signal corresponding to a first gamma value. The second setting unit generates a second setting signal corresponding to a second gamma value. The mapping unit maps the first gamma value and second gamma value to odd-numbered data lines and even-numbered data lines of the data lines respectively according to the first setting signal and second setting signal. The source driving unit outputs the first gamma value and second gamma value to odd-numbered display lines and even-numbered display lines of display lines of a display panel respectively.

An eye protecting method in an electronic device with storage device determines eyesight of a user who is using an electronic device, acquires light intensity of the environment, and distance of eyes of a user from the device, and applies a preferred display brightness value which is associated with the readings. The method may also cause display of warnings to the user as to eye-distance from the device and current time period spent watching the device.

The present disclosure discloses a display device and a driving method thereof. The driving method includes: when an anti-peep mode is enabled, generating M-frame sub-picture information and M-frame raster picture information according to information of a current picture frame to be displayed; controlling a sub-display panel in the display device to sequentially display M sub-pictures according to the M-frame sub-picture information, controlling pixel rows of the sub-pictures to be periodically arranged and displayed as first pixel groups, and controlling the first pixel groups of the pixel rows corresponding to the sub-pictures to be mutually misaligned; and controlling a sub-raster panel in the display device to sequentially display M raster pictures according to the M-frame raster picture information, and controlling pixel rows of the raster pictures to be periodically arranged and displayed as second pixel groups.

Provided is a liquid crystal display device including: a liquid crystal panel including display units for displaying an image using a veil-view function; and a control circuit. The display units each include a pair of sub-pixels including a first sub-pixel and a second sub-pixel. The liquid crystal panel sequentially includes an active matrix substrate, a first alignment film, a liquid crystal layer containing liquid crystal molecules, a second alignment film, and a counter substrate. The active matrix substrate includes first and second electrodes that are stacked via a first insulating layer or that face each other on the first substrate. At least one of the first or second electrode is disposed for each first sub-pixel and for each second sub-pixel. The counter substrate includes a third electrode. The control circuit is configured to switch between application of alternating voltage and application of constant voltage to the third electrode.

A pixel structure, including a first color pixel, a second color pixel and a third color pixel. The first color pixel includes a first-color normal-viewing sub-pixel and at least one first-color side-viewing sub-pixel. The second color pixel includes a second-color normal-viewing sub-pixel and at least one second-color side-viewing sub-pixel. The third color pixel includes a third-color normal-viewing sub-pixel and at least one third-color side-viewing sub-pixel. First color light emitted from the first-color normal-viewing sub-pixel, second color light emitted from the second-color side-viewing sub-pixel, and third color light emitted from the third-color side-viewing sub-pixel are mixed to obtain a white emission in a first side view direction.

The display panel includes a display area including a pixel area, and a light blocking area which is adjacent to the pixel area, a first light emitting device which is in the pixel area of the display area and emits a light having a first wavelength range, a second light emitting device which is in the light blocking area of the display area and emits a light having a second wavelength range different from the first wavelength range, and a discoloration layer which is on the second light emitting device and is color-changeable by the light having the second wavelength range, the discoloration layer defining a first opening exposing the pixel area to outside the discoloration layer.

Apparatus and methods for displaying an image by a rotating structure are provided. The rotating structure can comprise blades of a fan. The fan can be a cooling fan for an electronics device such as an augmented reality display. In some embodiments, the rotating structure comprises light sources that emit light to generate the image. The light sources can comprises light-field emitters. In other embodiments, the rotating structure is illuminated by an external (e.g., non-rotating) light source.

An image forming system includes a spatial light modulator (SLM) including a plurality of pixels. Each pixel is configured to diffract incident light and cause the diffracted light to exit the SLM, where a first diffraction order of light exiting the SLM passes through a first exit pupil and higher diffraction orders of light exiting the SLM pass through additional exit pupils having different positions from the first exit pupil. Control logic operatively coupled to the plurality of pixels is configured to control each pixel to control its modulation of the light incident on the pixel and cause the plurality of pixels to collectively form an image at each exit pupil. A light source is configured to emit incident light toward the SLM. A resampling layer is configured to subsample each pixel electrode with two or more samples per pixel to increase a spacing between each exit pupil.

A video display device includes LED pixels, a memory, and a processor. The processor receives video data that includes video pixels that correspond to the LED pixels. For at least some of the video pixels, the processor calculates a viewing angle for the LED pixel based on (i) a 3D location and optical axis vector for the LED pixel and (ii) a 3D location of a viewer of the LED pixel. The processor calculates a gain factor for the LED pixel based on the viewing angle and a relationship between pixel intensity and pixel viewing angle for the LED pixel. The processor calculates a compensated brightness for the LED pixel based on the gain factor and a brightness of the video pixel. The processor causes the LED pixel to emit light having the compensated brightness.

A system includes a spatial light modulator and a controller. The spatial light modulator is configured to perform phase modulation of a light that passes through a liquid crystal by applying individual voltages to the liquid crystal from each of a plurality of electrodes. The controller is configured to control the voltages applied to the liquid crystal from each of the plurality of electrodes based on phase image data. The phase image data represents values of each pixel corresponding to each of the plurality of electrodes by predetermined gradations. The controller converts gradation values, which are the values of each pixel, into voltages input to the electrodes corresponding to each pixel. The controller is configured to change a fluctuation width from a minimum value to a maximum value of the input voltages corresponding to a fluctuation width from a minimum value to a maximum value of the gradation values.