A gap adjusting device for adjusting the gap of displays adjacent to each other of a multi-display, is discussed. The gap adjusting device can include a locking part fastened to a first display, and having an uneven part formed thereon, a fastening part having one side end rotatably fastened to a second display adjacent to the first display, and having a fastening protrusion formed at the other side end thereof to be inserted into and fastened to the uneven part of the locking part, and an elastic member provided at the fastening part, and for applying an elastic force in order to keep a state where the fastening protrusion has been inserted into the uneven part of the locking part. According to such a configuration, it is possible to achieve the zero gap so that the gap does not occur between the displays, thereby enhancing the display quality of the multi-display.

A method of manufacturing a tiled display device is provided. In the method of manufacturing a tiled display device, a plurality of display panels are provided. Next, a plurality of alignment marks are provided. Afterwards, the plurality of display panels are tiled with reference to the plurality of alignment marks. The alignment marks are so arranged that the display panels are tiled to make all the same interpitches.

A tiled display device includes an array of a plurality of display panels. Each of the plurality of display panels includes a plurality of pixels constituting a plurality of pixel rows and a plurality of pixel columns, a data distributor disposed between a first pixel of a first pixel row among the plurality of pixel rows and a second pixel of the first pixel row adjacent to the first pixel in a first direction, and a scan driver disposed between the second pixel and a third pixel adjacent to the second pixel in the first direction.

A tiled display device is provided. The tiled display device includes a first panel and a second panel adjacent to the first panel. The first panel includes a first pixel unit, a second pixel unit and a third pixel unit. The second panel includes a fourth pixel unit, a fifth pixel unit, a sixth pixel unit, a seventh pixel unit, an eighth pixel unit and a ninth pixel unit. The second pixel unit, the fifth pixel unit, and the eighth pixel unit are arranged in a column and have a first color. The first pixel unit, the sixth pixel unit, and the seventh pixel unit are arranged in a column and have a second color. The third pixel unit, the fourth pixel unit and the ninth pixel unit are arranged in a column and have a third color.

A manufacturing method of an electronic device is provided by the present disclosure. The method includes: providing a substrate including a non-discarding portion and a discarding portion adjacent to the non-discarding portion; forming a first test wiring extending through the non-discarding portion and the discarding portion; cutting the substrate on a target line, wherein the target line is aligned with a boundary between the non-discarding portion and the discarding portion; performing a first conducting test on the first test wiring; and determining the substrate to be in an off-target cutting state when a result of the first conducting test is a short circuit state, or determining the substrate to be in an on-target cutting state when the result of the first conducting test is an open circuit state.

A display apparatus can include a plurality of first display panels arranged in a grid, the plurality of first display panels including display areas having a plurality of first sub-pixels and bezel areas free of sub-pixels; and a second display panel stacked on the plurality of first display panels, and including emission areas and transparent transmission areas, in which the emission areas of the second display panel include a plurality of second sub-pixels arranged in a grid overlapping with the bezel areas of the first display panels, and the transparent transmission areas of the second display panel overlap with the plurality of first sub-pixels in the plurality of first display panels.

The present disclosure contains embodiments of an apparatus, system and method designed to facilitate learning or efficient multitasking involving movement and solar energy where users' movement devices process or respond to different stimuli to facilitate users moving while learning, working, or participating in a simulation. In some embodiments this may be accomplished with the aid of a circular treadmill, spherical walkway, or combinable modular trackpads that may be linked to allow a user to lay the apparatus in a path suited for a plurality of environments. The embodiments of the disclosure involve the user moving while processing information and receiving feedback, assistance related to that movement, processing, or any combination thereof while combining the motion of the movement device with the feedback loop sent from sensor relays a user may receive an optimal experience for learning while moving. Some embodiments make efficient use of solar energy for classroom education management.

A device substrate includes a carrier, a device array, first fan-out lines, and second fan-out lines. The carrier has a first side, a second side, a third side, and a fourth side. The first side is opposite to the second side. The third side is opposite to the fourth side. The device array is disposed on a first surface of the carrier. The device array includes sub-pixels. Each of the sub-pixels includes a switching element and an optoelectronic element electrically connected with the switching element. The first fan-out lines are extending from the first side to the first surface and electrically connected with the device array. The second fan-out lines are extending from the second side to the first surface and electrically connected with the device array. The first fan-out lines and the second fan-out lines are asymmetrically disposed on the first side and the second side, respectively.

An electronic device may be provided with a display mounted in a housing. The display may have an array of display pixels that provide image light to a user. The array of display pixels may form an active display structure with a rectangular shape. The rectangular active display structure may be surrounded by an inactive border region. Optical structures such as upper structures formed from a sheet of glass and lower optical structures that lie beneath the sheet of glass may be configured to bend light from the display pixels along the periphery of the active display structure. The upper optical structures may have an area that is larger than the area of the active display structure, so that the presence of the optical structures may serve to enlarge the apparent size of the display. The lower and upper optical structures may have curved surfaces for bending the light.

The display device includes a first substrate, a second substrate, a red filter layer, a green filter layer, a blue filter layer, a first light emitting diode and a second light emitting diode. The red filter layer, the green filter layer and the blue filter layer are disposed between the first substrate and the second substrate. A portion of the red filter layer, a portion of the green filter layer and a portion of the blue filter layer are stacked with each other to form a light blocking structure. The first light emitting diode and the second light emitting diode are disposed between the first substrate and the second substrate and adjacent to each other. An orthographic projection of the light blocking structure on the second substrate is located between orthographic projections of the first light emitting diode and the second light emitting diode on the second substrate.