Provided is a method for adjusting a screen display direction and a terminal. The method includes the follows. At least one authority fingerprint is acquired, and the authority fingerprint is a fingerprint having the authority of changing a screen display direction. A first fingerprint is acquired. When the first fingerprint is the authority fingerprint, an input direction of the first fingerprint is acquired. The screen display direction is adjusted according to the input direction of the first fingerprint. If the first fingerprint is acquired again, a time period for acquiring the first fingerprint is recorded. The size of the screen display area is adjusted according to the recorded time period of the first fingerprint.

Videos are to be displayed in parallel, without missing information or a decrease in efficiency in the usable display region.

The aspect ratio of the large screen of an information processing apparatus 100 is 16:9, which is compatible with a Hi-Vision video. In a case where the large screen is used in a portrait layout, if the large screen is divided into three small screens in the vertical direction, the aspect ratio of the small screens after the dividing is 9:16/3=16:9.48. With respect to the original video content at 16:9, the ratio in inches is 9/16=56.25% (the area ratio is (9/16).sup.2=31.64%). Accordingly, the usable display region can be efficiently used.

Disclosed is an electronic device including a touch sensor configured to sense at least one touch on at least two different lateral sides of the electronic device, and a controller configured to determine a state of the electronic device when the electronic device has been gripped, determine a grip pattern based on the sensed at least one touch on the at least two different lateral sides of the electronic device, and perform a function based on the determined grip pattern and state of the electronic device.

Disclosed is an electronic device including a touch sensor configured to sense at least one touch on at least two different lateral sides of the electronic device, and a controller configured to determine a state of the electronic device when the electronic device has been gripped, determine a grip pattern based on the sensed at least one touch on the at least two different lateral sides of the electronic device, and perform a function based on the determined grip pattern and state of the electronic device.

A manufacturing apparatus includes a manufacturing unit; a cover that includes a see-through portion; an input unit that occupies a predetermined area on a surface of the see-through portion and detects a contact to the predetermined area and outputs information regarding the detection; a display that displays a predetermined image at a position of the cover; and a controller that in response to a predetermined input to the input unit, controls the display to display the predetermined image at or near a position where the predetermined input is detected, controls the display to display a predetermined operation panel image as the predetermined image at or near a position on the cover that overlaps the input unit; and controls the manufacturing unit based on a detection position of the predetermined input on the predetermined operation panel image.

An information processing method includes defining a virtual space for immersing a user wearing a head mounted display (HMD). The virtual space includes a viewpoint of the user, a sound collecting object separated from the viewpoint of the user, and a sound source object. The method includes processing sound data based on a relative positional relationship between the sound collecting object and the sound source object. The method includes instructing a sound outputting unit to output a sound based on the processed sound data. The method includes determining whether or not the viewpoint of the user is moved without synchronization with the movement of the HMD. In response to a determination that the viewpoint of the user is moved without synchronization with movement of the HMD, moving the sound collecting object so that the distance between the moved viewpoint of the user and the sound collecting object is decreased.

An information processing method includes defining a virtual space for immersing a user wearing a head mounted display (HMD). The virtual space includes a viewpoint of the user, a sound collecting object separated from the viewpoint of the user, and a sound source object. The method includes processing sound data based on a relative positional relationship between the sound collecting object and the sound source object. The method includes instructing a sound outputting unit to output a sound based on the processed sound data. The method includes determining whether or not the viewpoint of the user is moved without synchronization with the movement of the HMD. In response to a determination that the viewpoint of the user is moved without synchronization with movement of the HMD, moving the sound collecting object so that the distance between the moved viewpoint of the user and the sound collecting object is decreased.

A method for preventing burn-in conditions on a display of an electronic device is disclosed. The electronic device acquires a position of, for example, a task bar being displayed on an OELD screen, extracts a color of a pixel located adjacent to the task bar, and generates an overlay window of a color based on the extracted color. The color of the overlay window is translucent and continuously changes from the extracted color to black with an increase of the distance from the pixel located adjacent to the task bar. The task bar is displayed on the OELD screen with the overlay window overlaying the task bar.

A method for preventing burn-in conditions on a display of an electronic device is disclosed. The electronic device acquires a position of, for example, a task bar being displayed on an OELD screen, extracts a color of a pixel located adjacent to the task bar, and generates an overlay window of a color based on the extracted color. The color of the overlay window is translucent and continuously changes from the extracted color to black with an increase of the distance from the pixel located adjacent to the task bar. The task bar is displayed on the OELD screen with the overlay window overlaying the task bar.

A system and method for optimizing a display layout of multiple video streams at a sink device is provided. The display layout of multiple streams may be dynamically optimized based on a number of different variables, including characteristics of the sink device, total number of active incoming streams, active audio, and other characteristics of the source material or device. The source of an incoming media stream may contain useful characteristics for optimizing the display layout of multiple media streams. One such characteristic of a source device may include the device type, such as laptop, PC, phone, or tablet. Information may be extracted from each incoming stream in order to predict a source device type from which the incoming media stream originates.