The present application discloses a display panel and a display device, belonging to the field of display technology. The display panel comprises: a first display substrate and a second display substrate, the resolution of the second display substrate being higher than the resolution of the first display substrate; and the second display substrate has a through recess, and the orthographic projection of the first display substrate on the second display substrate covers the area where the through recess is located. The first display substrate has good light transmittance; thus, when a photosensitive sensor such as a front camera and a light sensor is located on the side of the first display substrate away from a light emission surface and a photosensitive surface of the photosensitive sensor faces the first display substrate, the photosensitive sensor can collect ambient light passing through the first display substrate, so that the photosensitive sensor can be normally used. In this way, it can be ensured that the display panel is an integral display panel while ensuring normal usage of a photosensitive sensor, effectively improving the integrity of the display panel.

The invention relates to a display device having an integrated, optically operating proximity sensor system (76) for detecting an object present within an observation space in front of the display device, such as a hand or a finger of a hand of a person. The display device is provided with a display unit (11) which has a front side (60) having an information-displaying display surface (62) and having an edge region (64), which adjoins said display surface and is not used for the display of information, and a rear side. The display device also has a proximity sensor system (76) having at least one transmitter (78) for emitting sensor radiation towards the observation space and having at least one receiver (74) for receiving sensor radiation reflected from the observation space. Said proximity sensor system (76) is arranged at least partially in the edge region (64) of the front side (60) of the display unit (11) in which at least one receiver of the proximity sensor system (76) is arranged in thin-film technology. The at least one transmitter (78) of the proximity sensor system (76) can be integrated either below the display unit (11) or therein.

A display panel includes: a display active area having multiple pixels; a bezel surrounding the display active area; a connector tab attached to the bezel at a first edge of the bezel; and a power line(s) formed from an opaque material, the power line(s) extending from the connector tab to a second edge of the bezel opposite the first edge, the power line(s) being configured to supply electrical power to the display active area, the power line(s) having a first width in a plane of the display along a side edge of the bezel between the first and second edges and, at a portion of the bezel at the second edge, a second width narrower than the first width or a gap in the power lines, the portion of the bezel at the second edge being substantially transparent.

A sensor-embedded display panel includes a substrate, a light emitting element on the substrate and including a light emitting layer, and a photosensor on the substrate and including a photoelectric conversion layer in parallel with the light emitting layer along an in-plane direction of the substrate, wherein the light emitting element and the photosensor each include a separate portion of a first common auxiliary layer that is a single piece of material that extends continuously on the light emitting layer and the photoelectric conversion layer, and a separate portion of a common electrode on the first common auxiliary layer and is configured to apply a common voltage to both the light emitting element and the photosensor, and the photoelectric conversion layer includes a sequential stack from the first common auxiliary layer of a first n-type semiconductor layer, a second n-type semiconductor layer, and a p-type semiconductor layer.

A light-receiving device that is highly convenient, useful, or reliable is provided. The light-receiving device includes a light-receiving layer between a pair of electrodes, the light-receiving layer includes an active layer and a hole-transport layer, the hole-transport layer contains a first organic compound, and the first organic compound is an aromatic monoamine compound or a heteroaromatic monoamine compound having at least one skeleton of biphenylamine, carbazolylamine, dibenzofuranylamine, dibenzothiophenylamine, fluorenylamine, and spirofluorenylamine. Alternatively, the light-receiving device includes a light-receiving layer between a pair of electrodes, the light-receiving layer includes an electron-transport layer and an active layer, the electron-transport layer contains a second organic compound, and the second organic compound includes a triazine ring.

An electronic device in various embodiments may include: a front cover forming a front surface of the electronic device; a rear cover forming a rear surface opposite to the front surface; a display placed between the front cover and the rear cover and visually exposed through the front cover; a first camera disposed on the front surface; and a processor operatively connected to the first camera and the display. The display may be divided into a display region and a sensor region when facing the front surface. The display may include: a light-emitting/light-receiving layer including light-emitting diodes disposed in the display region and at least one photodiode disposed in the sensor region; and a filter layer placed between the front cover and the light-emitting/light-receiving layer and including light-emitting filters aligned with the light-emitting diodes in the display region, and at least one light-receiving filter aligned with the at least one photodiode in the sensor region. The processor may be configured to receive, from the at least one photodiode, light information related to light passed through the at least one light-receiving filter to be received by the at least one photodiode, and perform, by the light information, a function related to an image acquired from the first camera to be displayed on the display.

A display device and a fingerprint recognition method are provided. The fingerprint recognition device includes at least two photosensitive regions receiving different colors of light, and the color of the light received by one photosensitive region corresponds to the emitted color of the light emitting sub-pixel in one color.

A display apparatus capable of performing image capturing with high sensitivity is provided. The display apparatus includes a light-emitting element including a light-emitting layer, and a light-receiving element including a photoelectric conversion layer. A transflective electrode is provided over the light-emitting layer, and a transparent electrode is provided over the photoelectric conversion layer. With a structure where the transflective electrode does not overlap the photoelectric conversion layer, a reduction in light-receiving sensitivity of the light-receiving element can be prevented while a microcavity structure is used for the light-emitting element. Thus, the display apparatus can emit light with high color purity and perform image capturing with high sensitivity.

The present disclosure provides a display device, a display apparatus, and a method for manufacturing a display device. The display device comprises a mainboard, a display panel disposed on the mainboard, and a fingerprint recognition sensor. The fingerprint recognition sensor is disposed on the mainboard, and the fingerprint recognition sensor is located between the mainboard and the display panel. A groove is formed on a surface of the display panel facing the mainboard, and an orthographic projection of the groove on the mainboard corresponds to a position of the fingerprint recognition sensor. The groove is configured to form an air gap between the fingerprint recognition sensor and the display panel.

A display device includes a display panel comprising a through hole and a pixel area, the pixel area surrounding the through hole and including pixels for displaying an image; a force sensor at a first surface of the display panel and configured to sense force applied from an outside; and a light sensor overlapping the through hole of the display panel in a thickness direction of the display panel, the light sensor being configured to sense light incident on the light sensor through the through hole.