A display device and a method for operating a display device disclosed herein include transmitting a proximity signal from a proximity sensor, the proximity sensor being positioned under a lower surface of a surface layer with an illumination component being positioned between the surface layer and the proximity sensor, in response to the illumination component being deactivated, receiving a reflected proximity signal based on the proximity signal, determining a proximity value based on the reflected proximity signal and modifying an operation of the display device based on the proximity value. The modifying the operation of the display device includes any one or a combination of activating the illumination component, deactivating the illumination component, or modifying a property of the illumination component

Provided is a field sequential image display device with which the service life of DMD display elements can be lengthened. In the present invention, each frame is equipped with: a display period, wherein a display control portion normally drives multiple mirrors and a lighting control portion drives a first lighting portion and a second lighting portion, thereby displaying a display image in display elements; and a non-display period, wherein the display control portion drives the multiple mirrors for a non-display period and the lighting control portion turns off the first lighting portion and the second lighting portion, and thus the display image is not displayed in the display elements. On the basis of prescribed luminance control conditions, when the luminance of the display image is to be lower than a predetermined threshold luminance value, a control unit lowers the display period ratio, which is the ratio of the display period in each frame period.

A control method for a backlight unit, a display panel, and a display device are disclosed. The control method includes obtaining ambient temperature through a temperature detection module; comparing the ambient temperature with a first standardized temperature reference value; and determining a driving mode of a light-emitting unit included in the backlight unit based on a comparison result. When the ambient temperature is higher than or equal to the first standardized temperature reference value, a driving method includes first driving subfields, and each of the first driving subfields consists of a bright subfield and a dark subfield.

The application discloses an image display device and a control method thereof. The control method for the image display device includes: receiving a first image signal from a host and displaying a frame, a first frame data of the first image signal having a first frequency; determining that the image display device enters a Motion Blur Reduction (MBR) mode and writing a double frequency of a vertical synchronous signal into a storage unit; and informing the host to read the storage unit and alternatively outputting a second frame data and a black-insertion frame data from the host, the second frame data having a second frequency higher than the first frequency.

A display device that includes a liquid crystal (LC) panel, a back light unit (BLU), a first data driver, and a second data driver. The back light unit (BLU) emits light during an illumination portion of a frame period and does not emit light during a remaining portion of the frame period. A first data driver writes data to a first portion of the pixels of the LC panel. A second data driver writes data to a second portion of the pixels of the LC panel. The first and second data drivers write data at an overlapping time during a write portion of the frame period. The write portion overlaps in time with the remaining portion of the frame period during which the BLU does not emit light.

A display apparatus includes: a first wiring, a second wiring, and a third wiring; a light emitting element configured to emit light due to a current flowing between an anode electrode and a cathode electrode; a driving transistor configured to control a current which is supplied from the first wiring to the anode electrode; a first switch configured to connect or disconnect the second wiring and a gate electrode of the driving transistor; a second switch configured to connect or disconnect the third wiring and the anode electrode; and a switching circuit configured to selectively apply one of an image signal voltage and a first voltage to the second wiring.

The illumination optical system is capable of reducing, without moving any optical member and without causing flicker when displaying a still image, sample-and-hold blur when displaying a moving image. The illumination optical system (20) respectively guides multiple light fluxes (Li, Lii, Liii) from multiple light sources (i, ii, iii) in a light source unit (10) to multiple illumination regions (4a, 4b, 4c) on an illumination surface (4). The illumination optical system includes an integrator optical system (1, 2) located between the light source unit and the illumination surface. The integrator optical system includes a first lens array (1) and a second lens array (2) each including multiple lens cells in order from a light source unit side. The illumination optical system changes illumination states of the multiple illumination regions depending on changes of states of the light sources.

The present disclosure relates to a method and a device for adjusting a MINI LED backlight television picture, and discloses that when a television backlight module adopts a MINI LED backlight lamp bead, according to a route of a motion track in a motion picture, the next dark field in an edge area is pre-lightened at a higher refresh rate or an edge of a bright picture is subjected to black shielding when a brightness of previous and next frames changes obviously, thereby improving the picture display effect.

A display panel driving method for driving a LED module of an electronic device to emit light, the method includes steps: controlling to scan a left-eye image and a right-eye image when the electronic device works at a 3D mode (S401); controlling the LED module to turn off and does not emits light during a predetermined period less than a scanning time of the left-eye image or the right-eye image, after switching to scan the left-eye image and the right-eye image (S402); and controlling the LED module to turn on and emit light after the predetermined period has passed (S403). The present invention also provides a backlight control circuit and an electronic device, the present invention capable of controlling the backlight module to emit light via the same signal and do not cause the interference between different signals.

In an image display device having a backlight including a plurality of light sources, the backlight is divided into a plurality of areas arranged in the same direction as an order of writing to pixels. A backlight drive circuit sets lighting periods separately for each of the areas and causes the brightness of the light sources to rise and drop in a non-step manner during the corresponding lighting period. In a case where first and second areas are adjacent to each other, there is a period of overlap between a lighting period set for the first area and a lighting period set for the second area, and the period of overlap includes a middle portion in which the brightness of light sources corresponding to the first area drops and the brightness of light sources corresponding to the second area rises.