An electronic device is provided. The electronic device includes a display, a display driver integrated circuit (IC) that controls the display, a camera disposed in a display area, and a processor connected with the display driver IC and the camera. The display includes a normal area having a first pixel density, a camera light-receiving area where the camera is disposed and at least one pixel is disposed, the camera light-receiving area having a second pixel density lower than first pixel density, and a circuit area provided between the normal area and the camera light-receiving area and having a third pixel density, and a circuit that transfers a drive voltage to the pixel disposed in the camera light-receiving area is disposed in the circuit area. The third pixel density is lower than or equal to the first pixel density, and the third pixel density is higher than the second pixel density.

According to some embodiments, a processor reads a force from a touch control. Hysteretic behavior is provided through at least three different actuation states and at least four different force threshold values, allowing user-friendly control of disparate actions through one touch interface with applications in volume control, photography, and user authentication. Other possibilities are shown and discussed.

This application discloses a display method for a foldable screen, applied to an electronic device including a foldable screen. The foldable screen can be folded to form at least two screens, and the at least two screens may include a first screen and a second screen. The method includes: When the foldable screen is in an expanded state, the electronic device displays a first interface of a first application in full screen on the foldable screen. The first interface includes an image captured by a camera. When detecting that the foldable screen changes from the expanded state to a half-folded state, the electronic device displays a second interface on the first screen. In this way, a user can conveniently perform photographing, video calling, live broadcasting, or the like without holding the electronic device steady with both hands.

The embodiments of the present application disclose an electronic device, and the electronic device includes: a device body and a camera apparatus, where a sound-emitting device is installed in the device body, a first sound cavity is provided on the device body, the first sound cavity has an opening that communicates with the outside, the camera apparatus is detachably installed in the first sound cavity, in a case that the camera apparatus is installed in the first sound cavity, the sound cavity of the sound-emitting device has a first volume value, in a case that the camera apparatus is separated from the device body, the sound cavity of the sound-emitting device extends toward the first sound cavity and has a second volume value, and the first volume value is smaller than the second volume value.

The present invention relates to a device and a control method therefor and, more specifically, the device comprises: a memory for storing at least one command; a depth camera for capturing at least one hand of a user; a display module; and a controller for controlling the memory, the depth camera, and the display module. The controller controls the depth camera so as to capture the at least one hand of a user and controls the display module so as to output a visual feedback that changes on the basis of the captured hand of a user.

The present invention discloses a method, a device and a mobile browser client for realizing centralized management of intelligent hardware devices by an APP, wherein the method comprising: identifying identification information of an intelligent hardware device via an identification interface provided by an APP on a mobile terminal; based on the information identifying, establishing a bluetooth connection between the mobile terminal and the intelligent hardware device; acquiring, by the APP, hardware controlling information of the intelligent hardware device through the bluetooth connection; and providing, in the APP, a display interaction interface which is based on the hardware controlling information.

A server device transmits picture image data to an image printing device, and transmits, to a portable terminal, moving image data corresponding to the picture image data. The server device includes a storage unit storing the picture image data and the moving image data, a picture-image data transmission unit transmitting the picture image data to the image printing device, a storage location information transmission unit transmitting storage location information of the moving image data to the image printing device, and a moving-image data transmission unit transmitting the moving image data to the portable terminal that has read, from a printed matter on which the picture image data and a code image obtained by coding the storage location information are printed by the image printing device, the code image, that has acquired the storage location information from the read code image, and that has accessed the server device.

Various embodiments for creating media clips are disclosed. In one example, a method is performed by a server for managing the creation and distribution of media clips, where the server associates a content capture device with an event, the content capture device for recording at least a portion of the event, receives a tag notification from a content tagging device via a network interface, generates a media clip creation command to the content capture device via the network interface, sends the media clip creation command to the content capture device, and receives a media clip created by the content capture device in response to receiving the media clip creation command.

The control module outputs a control signal to control the first image capture module and the second image capture module to be in a working state in a time-sharing manner. A first signal interface is electrically connected to the first node. The first optimization unit is electrically connected between the first node and the first image capture module, and the second optimization unit is electrically connected between the first node and the second image capture module. The first optimization unit is configured to ensure the smoothness of a curve of a first image signal corresponding to a first image captured when the first image capture module is in the working state, and the second optimization unit is configured to ensure the smoothness of a curve of a second image signal corresponding to a second image captured when the second image capture module is in the working state.

An imaging method is provided for a modular mixed reality (MR) device having an MR calculation module, an MR optical path module and an MR posture module. The MR calculation module is configured to adjust display content according to data from the MR posture module. The MR optical path module comprises a virtual-image optical path and a mixed optical path. A semi-transparent semi-reflective mirror is provided in the mixed optical path. One surface of the mirror is a real-image introduction surface facing a real environment, while the other is a virtual-image introduction surface facing the virtual-image optical path. Virtual-image light is reflected by the virtual-image introduction surface onto an observation end and mixed with real environment light transmitted to the observation end by the real-image introduction surface to form a mixed reality image.