An electronic panel includes a base substrate having a first area, a second area adjacent to the first area, and a third area adjacent to the second area, a plurality of pixels in the second area, a plurality of pixel signal lines in the third area and connected to the pixels, a crack detecting pattern spaced apart from the pixels and in the first area, a first line spaced apart from the pixel signal lines, in the third area, and connected to a portion of the crack detecting pattern, and a second line spaced apart from the pixel signal lines, in the third area, connected to another portion of the crack detecting pattern, and spaced apart from the first line. The crack detecting pattern has a line-symmetrical shape with respect to a symmetry axis passing through a center of the first area.

A display apparatus includes: a substrate; a plurality of unit display portions, each including a thin film transistor located on the substrate and including at least one inorganic layer, a display element electrically connected to the thin film transistor, and a planarization layer located between the thin film transistor and the display element; and an encapsulation layer sealing each of the plurality of unit display portions, the planarization layer including a recess that is concave in a depth direction from a side of the display element.

Provided are a driving substrate, a light emitting apparatus and a manufacturing method therefor, which relate to the technical field of display. According to the present disclosure, a rigid substrate, a debonding layer, a first buffer layer, an organic material layer, a second buffer layer and a wiring layer are sequentially arranged in layer configuration in a component disposing area and a circuit board binding area, and the first buffer layer, an overlapping electrode layer, the organic material layer and the second buffer layer are sequentially arranged in layer configuration in a bending area. Two ends of the overlapping electrode layer respectively extend to the component disposing area and the circuit board binding area, and the wiring layer of the component disposing area and the wiring layer of the circuit board binding area are respectively connected to the overlapping electrode layer through via holes.

A display device is discussed, which has improved transmittance and relieves a visual difference in a camera region, even though a camera is provided in an active region, by changing the configuration of a substrate in a region corresponding to the camera.

A display device includes: a display panel in which a first panel region, a bending region, and a second panel region are arranged along a first direction; a support layer below the first panel region of the display panel, wherein the bending region of the display panel is bent toward a lower portion of the support layer; a portion of the support layer is between the first panel region and the second panel region; a first alignment mark in the first panel region; and a first alignment opening overlapping the first alignment mark in the support layer, wherein in a thickness direction of the display panel, the first alignment opening is spaced apart from the second panel region, the first alignment opening is spaced apart from an edge of the support layer, and the first alignment opening is completely surrounded by the support layer.

A display panel for a display device includes a display area in which a plurality of sub-pixels are disposed and a camera area which is adjacent to the display area and in which a first hole is disposed; a first plate disposed on a rear surface of the display panel and including a second hole overlapping the first hole; a front member disposed on an upper surface of the display panel; and a light blocking member covering a rear surface of the front member which is exposed through the first hole, an inner surface of the first hole, and an inner surface of the second hole.

A flexible display device may include a display panel that is divided into an active area, a non-active area, and a bending area and having one edge that is bent in a rear direction to have a predetermined curvature, first and second back plates disposed on a rear surface of the display panel, a metal plate disposed on a rear surface of the first back plate and a coating layer disposed on an exposed rear edge of the metal plate. Accordingly, device set-up time can be shortened, and alignment accuracy can be improved.

A display apparatus includes a pixel electrode, a pixel-defining layer covering edges of the pixel electrode, where an opening is defined through the pixel-defining layer to expose a central portion of the pixel electrode, and a light-condensing layer disposed over the pixel electrode to correspond to the opening. A first first slope angle of a first first side surface of the light-condensing layer with respect to a lower surface of the light-condensing layer is different from a second first slope angle of a second first side surface of the light-condensing layer with respect to the lower surface.

A display device includes a display unit comprising a plurality of light-emitting areas emitting light. A touch sensing unit is disposed on the display unit to sense a touch. A buffer part is disposed on the touch sensing unit to cushion an external impact. A metal pattern is disposed on the buffer part and has a mesh structure. The metal pattern includes a plurality of code patterns having a cut shape that encodes position information.

High-efficiency plasmonic OLED displays are provided that use the design of the plasmonic device to overcome some of the shortcomings of conventional display panels. Control of the Stokes parameters of the emitted light and/or modification of the ambient light incident on the device relative to the emitted light is used to maximize the amount of visible light emitted by the display.