A VR system, a wearable apparatus and a method for controlling a VR apparatus are disclosed. The wearable apparatus comprises a communication circuit, a processor, and a touch screen which are connected to one another successively; the communication circuit establishes a connection to the processor, and is configured to acquire control request information; the processor displays a control interface on the touch screen based on the control request information, generates control information based on touch actions performed on the control interface, and further sends the control information to the VR apparatus to control the VR apparatus via the control information. In this way, the present application may improve the user experience.

This application relates to the field of display technologies, and provides a method and an apparatus for adjusting an orientation, and an electronic device. The method comprises: in response to a first rotation operation performed by a user on an electronic device, performing the first rotation operation on an orientation of content displayed on the screen of the electronic device; determining whether an orientation of the screen of the electronic device is consistent with the orientation of the content after the first rotation operation is performed; and in response to that the orientation of the screen of the electronic device is inconsistent with the orientation of the content after the first rotation operation is performed, performing a second rotation operation on the content. By using the method, the apparatus, and the electronic device provided in embodiments of the present invention, content displayed on the electronic device can be adjusted to an orientation suitable for a user to view, and the user does not need to perform a specified gesture or enter an edit interface to perform a rotation operation, thereby simplifying a user operation and improving user experience.

The present invention relates to a flexible transparent display sheet, and an image display apparatus including the same. The flexible transparent display sheet according to an embodiment of the present disclosure includes: a base disposed in a display area and a connection area; a metal layer formed on the base; an anti-oxide layer formed on a portion of the metal layer; a plurality of solders formed on a portion of the anti-oxide layer; a plurality of light emitters, each of which is connected to each of the plurality of solders; and an insulation layer disposed in the connection area and formed on the anti-oxide layer. Accordingly, a flexible transparent display sheet having an integrally formed power connector may be provided.

A device, a method, and a system recognize a motion using a gripped object. The motion recognition device may estimate a state of a wrist of a user according to a writing action using the gripped object and may estimate a joint motion of a body part related to the wrist according to the writing action. The device may then estimate a state of the gripped object according to the state of the wrist and the joint motion. Additionally, the motion recognition device may control an external device by using a control signal generated by continuously tracking the state of the object.

A virtual keyboard includes a pad, a number of motion sensors coupled to the pad to detect the presence of a user's hands over the pad, a processor, and a memory. The memory includes executable code that, when executed by the processor calibrates the virtual keyboard based on a number of criteria of the user's hand upon detection of the user's hands by the motion sensors, in which the criteria comprises the user's unique keyboard profile.

A display panel includes a substrate, pixel electrodes, switching components, an electrode, a line, a terminal, an insulating film, and a conductive film. The switching components are disposed in a layer lower than the pixel electrodes. The electrode is disposed in a layer different from a layer in which the pixel electrodes are disposed. The line includes sections disposed in a layer lower than the switching components in a display area. The terminal is disposed in a layer upper than the line in a non-display area. The insulating film includes a section disposed between the line and the switching components in the display area and a section disposed between the terminal and the substrate in the non-display area. The conductive film is disposed on the insulating film in a layer between the line and the terminal to connect the line to the terminal.

Embodiments provide for a handheld device with a unified desktop for integrating the functionality of the handheld device with a larger computer system. When connected to a peripheral display and/or a display of the larger computer system, the handheld device provides a unified desktop displayed across the screen(s) of the handheld device and the peripheral display. The unified desktop unifies the functionality provided by the larger computer system and the handheld functionality, e.g., communication applications (e.g., phone, SMS, MMS). A user can seamlessly interact with applications, e.g., open, move, close, receive notifications, on the unified desktop whether the applications are displayed on the screens of the handheld device, or the peripheral display of the larger computer system.

Embodiments provide for a handheld device with a unified desktop for integrating the functionality of the handheld device with a larger computer system. When connected to a peripheral display and/or a display of the larger computer system, the handheld device provides a unified desktop displayed across the screen(s) of the handheld device and the peripheral display. The unified desktop unifies the functionality provided by the larger computer system and the handheld functionality, e.g., communication applications (e.g., phone, SMS, MMS). A user can seamlessly interact with applications, e.g., open, move, close, receive notifications, on the unified desktop whether the applications are displayed on the screens of the handheld device, or the peripheral display of the larger computer system.

In one embodiment, a method includes detecting a touch of an object on a device. The method further includes predicting an area of the device to which the detected touch will move. Predicting the area of the device to which the detected touch will move is based at least in part on the following: a size of a footprint of the object, a speed of travel of the object, a latency associated with the object, a drive line pitch of a touch sensor of the device, and a frame rate.

Methods and devices for selectively presenting a user interface after waking from a stand-by mode. More particularly, the method includes a device entering a stand-by mode while in a first orientation or state. While in the stand-by mode, the device changes orientation or state. The device can determine the new orientation or state upon waking and provide the appropriate display for the new orientation or state.