A display apparatus includes: a light-emitting device layer provided to extend over a plurality of pixels arranged two-dimensionally; a phosphor layer separated by a partition wall for each of the pixels; and a bonding structure sandwiched between the light-emitting device layer and the phosphor layer, and in which a first oxidation film, a bonding oxidation film, and a second oxidation film are stacked in order from the light-emitting device layer side.

An electronic device is provided. The electronic device includes a deformable display panel, a sensor, a display driving circuit operatively coupled to the deformable display panel and the sensor, and comprising a graphical random access memory (GRAM), and a processor operatively coupled to the display driving circuit and the sensor, wherein the display driving circuit can be configured to, while the size of a displayable area of the deformable display panel is changed, store, in the GRAM, data for displaying an image of a first size received from the processor, receive, from the sensor, a signal for indicating that the size of the displayable area is a second size smaller than the first size, after the data is stored, and scan part of the data in response to the reception of the signal, thereby displaying an image of the second size through the deformable display panel.

A micro-LED display device and a manufacturing method thereof are disclosed. The method comprises: forming micro-LEDs (202) on a carrier substrate (201), wherein the carrier substrate (201) is transparent for a laser which is used in laser lifting-off; filling trenches between the micro-LEDs (202) on the carrier substrate (201) with a holding material (209); performing a laser lifting-off on selected ones of the micro-LEDs (202) to lift off them from the carrier substrate (201), wherein the selected micro-LEDs (202) are held on the carrier substrate (201) through the holding material (209); bonding the selected micro-LEDs (202) onto a receiving substrate (207) of the micro-LED display device; separating the selected micro-LEDs (202) from the carrier substrate (201) to transfer them to the receiving substrate (207).

A micro-LED display device and a manufacturing method thereof are disclosed. The method comprises: forming micro-LEDs (202) on a carrier substrate (201), wherein the carrier substrate (201) is transparent for a laser which is used in laser lifting-off; filling trenches between the micro-LEDs (202) on the carrier substrate (201) with a holding material (209); performing a laser lifting-off on selected ones of the micro-LEDs (202) to lift off them from the carrier substrate (201), wherein the selected micro-LEDs (202) are held on the carrier substrate (201) through the holding material (209); bonding the selected micro-LEDs (202) onto a receiving substrate (207) of the micro-LED display device; separating the selected micro-LEDs (202) from the carrier substrate (201) to transfer them to the receiving substrate (207).

Disclosed is a display device. The display device of the present disclosure includes: a display panel; a frame disposed at a rear of the display panel, and to which the display panel is coupled; and a corrugated panel disposed at the rear of the display panel, and to which the frame is coupled, wherein the corrugated panel includes: a front skin forming a front surface; a rear skin forming a rear surface and disposed opposite to the front skin; and a core disposed between the front skin and the rear skin, and having a corrugated shape with alternating ridges and grooves which are elongated, wherein a rear surface of the rear skin is formed to be flat.

A fitness equipment LED electronic meter, comprising a PCB, a support, and a panel, wherein the PCB is connected to the back surface of the support, and the panel is locked to the front surface of the support; the front surface of the PCB is provided with a display module consisting of a plurality of LEDs; a plurality of first grooves passing through the support are provided on the support; the LEDs are fitted in the first grooves; a diffusion film and a semitransparent plate are sandwiched between the panel and the support, and sequentially abut against the front surface of the support. The fitness equipment LED electronic meter improves the display effect of the electronic meter, avoids the situation that the display effect of the electronic meter is affected due to deformation of the panel and loosening of screws, and improves the fitness experience of people.

A fitness equipment LED electronic meter, comprising a PCB, a support, and a panel, wherein the PCB is connected to the back surface of the support, and the panel is locked to the front surface of the support; the front surface of the PCB is provided with a display module consisting of a plurality of LEDs; a plurality of first grooves passing through the support are provided on the support; the LEDs are fitted in the first grooves; a diffusion film and a semitransparent plate are sandwiched between the panel and the support, and sequentially abut against the front surface of the support. The fitness equipment LED electronic meter improves the display effect of the electronic meter, avoids the situation that the display effect of the electronic meter is affected due to deformation of the panel and loosening of screws, and improves the fitness experience of people.

A display backplane is provided, including a base, wherein pixel circuits, bonding electrodes, and bonding connection wires are on the base; the bonding electrodes are coupled to the bonding connection wires in a one-to-one correspondence; the bonding electrodes and the bonding connection wires are on two opposite surfaces of the base; the pixel circuits and the bonding connection wires are on a same side of the base; one end of each bonding connection wire is coupled to the bonding electrode through the first via in the base; the other end of each of at least some bonding connection wires is coupled to the pixel circuit; and an orthographic projection of at least one of the bonding electrodes and the bonding connection wires on the base is not coincident with an orthographic projection of the pixel circuit on the base.

A display panel and a display device are provided. The display panel includes: a primary contour defining an active display region and including first portions extending non-linearly, a secondary contour inside the primary contour and including second portions extending non-linearly; the primary contour is an outer contour after the display panel is lightened; pixels in the active display region include pixels of first type inside the secondary contour, pixels of second type intersecting the second portion, and pixels of third type intersecting the first portion and outside the secondary contour; an aperture ratio of pixels of third type is smaller than that of pixels of first type, an aperture ratio of at least part of pixels of second type is positively correlated with an area of a part, inside the secondary contour, of each pixel of second type.

A method of manufacturing a display substrate which includes a central display area and an arc-shaped stretch area located at a corner of the central display area, wherein the method includes: preparing a substrate to be etched, which includes a flexible substrate, a stack structure disposed on the flexible substrate, and a last-dry-etched metal layer disposed on a side of the stack structure away from the flexible substrate, the stack structure including an active layer, at least one conductive layer, and a plurality of insulating layers, wherein the last-dry-etched metal layer is a last metal layer that is formed through dry etching; and forming a stretch groove by patterning the substrate to be etched, wherein the stretch groove is disposed in the stretch area and passes through the stack structure and a part of the flexible substrate. A display substrate, a display panel and a display device are further provided.