A light emitting substrate, a light emitting motherboard, a method for obtaining a light emitting substrate, and a displaying device. The light emitting substrate comprises a substrate and multiple light emitting units, wherein the substrate is provided with a light emitting region and a bind region located on one side of the light emitting region; each light emitting unit comprises a light zone provided with at least one light emitting diode and a drive circuit provided with multiple pins, and the multiple light emitting units are arranged on the substrate in an array; a direction pointing from the light emitting region to the bind region is a first direction; and in the first direction, the drive circuit of at least one light emitting unit in the last row of the light emitting units is connected to an address line.

A display may have an array of pixels such as liquid crystal display pixels. The display may include short pixel rows that span only partially across the display and full-width pixel rows that span the width of the display. The gate lines coupled to the short pixel rows may extend into the inactive area of the display. Supplemental gate line loading structures may be located in the inactive area of the display to increase loading on the gate lines that are coupled to short pixel rows. The supplemental gate line loading structures may include data lines and doped polysilicon that overlap the gate lines in the inactive area. In displays that combine display and touch functionality into a thin-film transistor layer, supplemental loading structures may be used in the inactive area to increase loading on common voltage lines that are coupled to short rows of common voltage pads.

A display device includes a first liquid crystal panel, a second liquid crystal panel disposed on a back face side of the first liquid crystal panel, a position compensation unit that compensates for a display position of an image on the second liquid crystal panel based on position compensation information indicating a relative positional relationship between the first liquid crystal panel and the second liquid crystal panel, and an area expansion unit that expands a displayable area of the image before the display position is compensated for or a displayable area of the image after the display position is compensated for by the position compensation unit.

A display apparatus includes: a display panel including a display region, a first peripheral region, and a second peripheral region; and a circuit substrate. The display panel includes a gate drive circuit, n number of clock main lines, an outer main line and an inner main line, and a plurality of branch wiring lines. The first peripheral region includes a plurality of unit regions. The plurality of unit regions includes a first unit region and a second unit region. A resistance value of the at least one branch wiring line between the inner main line and the outer main line in the first unit region is smaller than a resistance value of the at least one branch wiring line between the inner main line and the outer main line in the second unit region.

Provided is a display system, including one or more display screens (11, 12), a plurality of source drivers (13, 14), a timing controller (15) and a graphics processing unit (16). Each display screen (11, 12) is connected to one or more source drivers (13, 14). The graphic processing unit (16) is connected to the timing controller (15). The timing controller (15) is connected to the plurality of source drivers (13, 14). The graphic processing unit (16) is configured to determine each image of the one or more display screens (11, 12) and transmit the image to the timing controller (15). The timing controller (15) is configured to divide each image of the one or more display screens (11, 12) into a plurality of sub-images in a P2P transmission manner, and output in parallel the corresponding sub-images to the plurality of source drivers (13, 14).

A first substrate of an electro-optical device is provided with a temperature detection circuit including a temperature detection element, and a first wiring line and a second wiring line of the temperature detection element are electrically connected to a first terminal and a second terminal, respectively. Between the first terminal and the second terminal, a third terminal that is not electrically connected to the temperature detection element is provided. Thus, through detection of a current at the time of applying a ground potential from a first probe and a second probe of an inspection device to the first terminal and the second terminal and applying a predetermined voltage from a third probe to the third terminal, insulation between the first terminal and the second terminal can be inspected.

A semiconductor device using a pass transistor is provided. The semiconductor device includes a first circuit, a second circuit, a plurality of input terminals, and an output terminal. The first circuit includes a plurality of first transistors functioning as pass transistors, and the second circuit includes a plurality of second transistors functioning as pass transistors. Note that the number of the first transistors is larger than the number of the second transistors, a gate of the first transistor is supplied with a first signal, and a gate of the second transistor is supplied with a second signal. The first circuit is supplied with grayscale signals through x input terminals, and the first circuit selects y grayscale signals of the grayscale signals with the first signal. The second circuit is supplied withy (y<x) grayscale signals, the second circuit outputs z (z<y) grayscale signals of they grayscale signals to the output terminal with the second signal.

A three-dimensional-image display device includes a display unit, a variable focus lens unit, and a controller. The display unit sequentially displays a first image displayed by a first image signal and a second image displayed by a second image signal, and that projects a display light of the first image and a display light of the second image. The variable focus lens unit switches the focal lengths for the display lights to respectively form, as virtual images, the first image and the second image on a first display surface and a second display surface. The controller controls, on the basis of a start timing at which writing, of an image signal of a different image, to pixels of the display unit starts, a projecting timing at which the display unit projects the display light of the first image and the display light of the second image.

A display apparatus includes: a display panel including a display region, a first peripheral region, and a second peripheral region; and a circuit substrate. The display panel includes a gate drive circuit, n number of clock main lines, an outer main line and an inner main line, and a plurality of branch wiring lines. The first peripheral region includes a plurality of unit regions. The plurality of unit regions includes a first unit region and a second unit region. A resistance value of the at least one branch wiring line between the inner main line and the outer main line in the first unit region is smaller than a resistance value of the at least one branch wiring line between the inner main line and the outer main line in the second unit region.

A multi-panel display device includes a first display device including a first display region and a first non-display region surrounding the first display region; a first optical member located on the first display device and including optical fibers; and a first protection film covering an outside of the first optical member.