The description relates to display devices. One example can include an integrative display chassis defining a major planar surface and having a feature formed relative to the major planar surface. The example can also include a display positioned relative to the integrative display chassis and extending along the major planar surface defined by the integrative display chassis. The example can further include an electronic component positioned in the feature and oriented relative to the major planar surface by the feature.

Provided is a display panel including a main display area, a component area having a transmissive area, a peripheral area outside the main display area, a substrate, a bottom metal layer on the substrate, and defining an opening corresponding to the transmissive area, a valley portion adjacent to a boundary between the bottom metal layer and the transmissive area, and a thin-film encapsulation layer on the valley portion, and including an inorganic layer and an organic layer.

An electronic device includes a communicator configured to perform communication with an external device, a display configured to display a UI (User Interface) element in a screen, and a processor. The processor receives through the communicator, touch panel information of the external device and first data according to a first input of a user detected on the touch panel of the external device, and changes a location of the UI element displayed on the screen based on the touch panel information and the first data.

A display module, including a display panel, a protective cover, and a camera module, is provided. The display panel includes a through-hole region provided with a through-hole, and a non-through-hole region. The protective cover is disposed on a light-emitting side of the display panel, and the camera module is disposed on a side facing away from the light-emitting side of the display panel. A lens of the camera module is disposed corresponding to the through-hole, a side of the protective cover close the display panel has an arc-shaped concave surface, and the arc-shaped concave surface is disposed corresponding to the through-hole.

Housings for electronic devices are disclosed. According to one aspect, adjoining surfaces of electronic device housings can be mounted or arranged such that adjoining surfaces are flush to a high degree of precision. The electronic devices can be portable and in some cases handheld.

A mobile computing device includes an emissive display panel configured to emit light from a front surface of the display panel, with the display panel having a plurality of transparent layers and an opaque back cover layer. The mobile computing device also includes a light sensor located behind the opaque back cover layer, and the opaque back cover layer includes an opening through which light from outside the display that is transmitted through the transparent layers of the display can pass to reach the sensor. An air gap separates the light sensor from the transparent layers of the display panel. The plurality of transparent layers includes a reflection attenuating layer on a back side of the display panel configured to attenuate the reflection of light from an interface between a transparent layer of the display panel and the air gap.

An electronic device is provided. The electronic device includes a housing and a display including a transparent plate forming a front of the electronic device, a display panel viewable from the front of the electronic device through the transparent plate, a panel flexible circuit film arranged under the rear surface of the display panel including a bending part that extends toward the front surface of the display panel in a region adjacent to a first side surface of the electronic device, the bending part being electrically connected to the display panel on the front surface of the display panel, and a first support member arranged between the rear surface of the display panel and the panel flexible circuit film, a partial region of the first support member having an area larger than that of the panel flexible circuit film within a designated distance from the first side surface.

An antenna assembly includes a conductive frame defining at least one slot and divided into at least a first conductive branch and a second conductive branch independently by the slot, a feed point being arranged on the first conductive branch; a resonant circuit, a signal source being coupled to and feeding a current signal to the first conductive branch through the resonant circuit and the feed point, the current signal being coupled to the second conductive branch through the slot, and multiple resonant frequencies being generated on the first and the second conductive branches through the resonant circuit; and a switching circuit configured between perform a switching adjustment for the current signal coupled to the second conductive branch such that radio frequency signals including multiple operating frequency bands are radiated simultaneously on the first conductive branch and the second conductive branch; at least two operating frequency bands being switchable.

A mounting apparatus may include: a mounting part on which a part of an external electronic apparatus is mounted; a film part connected to the mounting part; a near field wireless communication module; and a processor, wherein the processor may be configured to: detect a mounting state of the external electronic apparatus; determine whether the mounted external electronic apparatus is an apparatus supporting a holographic mode; and on the basis of the determined result, control to transmit a transmission signal to the external electronic apparatus by using the near field wireless communication module so that the external electronic apparatus outputs a hologram content by using at least a part of a display of the external electronic apparatus, and the hologram content output by the external electronic apparatus can be projected on the film part. Various other embodiments may be possible.

A pressure-sensitive vibration processing method can be applied to a mobile terminal including an application processor, a pressure sensor, and a vibration motor. The method can include: in a first state of the mobile terminal, notifying directly, with the pressure sensor, the vibration motor to generate vibration, when pressure received by the pressure sensor exceeds a threshold, the first state including a state where the application processor is in sleep; and in a second state of the mobile terminal, notifying, with the pressure sensor, the application processor to control the vibration motor to generate vibration, when pressure received by the pressure sensor exceeds the threshold, the second state including a state where the application processor is awake. A timely response is therefore ensured when vibration is needed, and it can also be ensured that various vibrations are handled normally during system operation to avoid abnormal vibration feedback.