A display assembly includes a display console having an image plane spaced from a touch plane. The touch plane includes at least one touch sensitive area. A controller is operatively connected to the display console, and includes a processor and tangible, non-transitory memory on which is recorded instructions for executing a method of dynamically adjusting at least one touch sensitive area in real-time. The controller may be programmed to determine respective correction shifts to each pixel in the touch sensitive area for multiple viewing positions of one or more users. The display console may be curved. The controller may be programmed to simultaneously a first correction shift to a first touch sensitive area for the viewing position of the first user and a second correction shift to a second touch sensitive area for the viewing position of the second user.

A display device employs a patterned quantum rod layer having pixel elements driven by pixel splitting to generate a privacy viewing mode. The display device includes a patterned quantum rod layer having first pixel elements including first quantum rods wherein the first quantum rods are aligned in a first alignment direction, and second pixel elements including second quantum rods wherein the second quantum rods are aligned in a second alignment direction different from the first alignment direction. An electronic controller is configured to perform pixel splitting whereby the electronic controller drives the first pixel elements and the second pixel elements such that the patterned quantum rod layer has an off-axis luminance different from an on-axis luminance to generate a privacy viewing mode. The first alignment direction may be oriented 90° relative to the second alignment direction.

A stretchable display device includes a first stretchable display panel and a second stretchable display panel overlapping the first stretchable display panel. The first stretchable display panel includes a first stretchable substrate having a first length and a plurality of first pixels spaced apart from one another on the first stretchable substrate. The second stretchable panel includes a second stretchable substrate and a plurality of second pixels spaced apart from one another on the second stretchable substrate. The first stretchable substrate is stretchable in a first direction to have a second length. When the first stretchable substrate is stretched to have the second length, the second pixels are each positioned between the plurality of first pixels when viewed from a plan view.

In order to achieve a display device that can display a plurality of images and also prevents a lowering of resolution of the images displayed by emitting light in a plurality of different direction from one pixel, a display device, which is a display device that can display at least two images by emitting light in at least two directions from each of a plurality of pixels, includes: a backlight unit, a backlight side substrate, a display side substrate, a MEMS shutter, and a display control unit. The display device can display an image for a first viewpoint and an image for a second viewpoint by the display control unit controlling the MEMS shutter for each of the pixels.

An optical axis of a light emitting element is inclined against a normal line of a light emitting surface of the light emitting element to a central side of a display area in a row direction according to positions of subpixels in the row direction, and the optical axis is inclined against the normal line of the light emitting surface to the central side of the display area in a column direction according to the positions of the subpixels in the column direction. A range of inclination of the optical axis is different in the row direction and the column direction. In the row direction and the column direction, the subpixels are disposed such that color filters of the same color are arranged in a direction in which the range of inclination becomes larger, and color filters of colors which are different from each other are arranged in another direction.

A grayscale value setting method for a liquid crystal panel is disclosed which includes obtaining actual luminance values of each grayscale G of the liquid crystal panel at front and slant view angles; dividing actual luminance values according to the area ratio of the main pixel area M and the sub pixel area S, and establishing corresponding relationships between the grayscale and the actual luminance values in the main and the sub pixel areas; calculating theoretical luminance values of each grayscale; setting a grayscale combination, such that a sum of difference values between actual and theoretical luminance values of the front and slant view angle are minimal; and repeating the last step to obtain grayscales respectively input to the main pixel and the sub pixel areas at all of grayscales of the liquid crystal panel. A liquid crystal display setting a grayscale value using the above method is also disclosed.

The application discloses a method for adjusting a wide viewing angle, including: obtaining gray scale values of two pixels located in a same column and two adjacent rows; obtaining a view angle value of a wide view angle, and determining a target difference value according to the view angle value; and reducing a gray scale value of one of the two pixels and/or increasing a gray scale value of another one of the two pixels according to the target difference value, to perform wide view angle adjustment of a picture to be displayed, wherein a difference value between the gray scale values of the two pixels after the wide view angle adjustment is greater than or equal to the target difference value. The application also discloses a display panel and a computer readable storage medium.

A driving method of a liquid crystal display panel is provided. The driving method includes: defining a first area and a second area on the liquid crystal display panel; generating at least two first display grayscales according to each first to-be-displayed grayscale corresponding to the first area and generating at least two second display grayscales according to each second to-be-displayed grayscale corresponding to the second area; and using the at least two first display grayscales to respectively drive at least two first pixels in the first area to display and using the at least two second display grayscales to respectively drive at least two second pixels in the second area to display. Therefore, a displayed image observed in an oblique viewing angle would exhibit a disordered state, the liquid crystal display panel can achieve anti-peep effect and the privacy of user can be effectively protected.

An image display device a light source, an image display layer and a refractive structure layer. The light source emits a light beam. The image display layer is located over the light source. The image display layer includes plural pattern sections. The refractive structure layer has a reference plane. When the light beam is irradiated on the refractive structure layer and there is a first angle between the light beam and the reference plane, the light beam is guided to a first pattern section, so that a first image is displayed on the image display layer. When the light beam is irradiated on the refractive structure layer and there is a second angle between the light beam and the reference plane, the light beam is guided to a second pattern section, so that a second image is displayed on the image display layer.

An image display device a light source, an image display layer and a refractive structure layer. The light source emits a light beam. The image display layer is located over the light source. The image display layer includes plural pattern sections. The refractive structure layer has a reference plane. When the light beam is irradiated on the refractive structure layer and there is a first angle between the light beam and the reference plane, the light beam is guided to a first pattern section, so that a first image is displayed on the image display layer. When the light beam is irradiated on the refractive structure layer and there is a second angle between the light beam and the reference plane, the light beam is guided to a second pattern section, so that a second image is displayed on the image display layer.