An input display device includes: a processor to execute a program; and a memory to store the program which, when executed by the processor, results in performance of steps including: receiving an input of a track by a receiving unit; generating a track image showing the track; acquiring a character string; and displaying the character string acquired in the acquiring to be superimposed on the track image. When the character string is acquired in the acquiring before the track image is generated, the displaying the character string is stood by.

Methods, devices, and computer programs for augmenting a virtual reality scene with real world content are provided. One example method includes an operation for obtaining sensor data from an HMD of a user to determine that a criteria is met to overlay one or more real world objects into the virtual reality scene to provide an augmented virtual reality scene. In certain examples, the criteria corresponds to predetermined indicators suggestive of disorientation of a user when wearing the HMD and being presented a virtual reality scene. In certain other examples, the one or more real world objects are selected based on their effectiveness at reorienting a disoriented user.

Systems and methods are described for navigating through a data space. The navigating comprises detecting a gesture of a body from gesture data received via a detector. The gesture data is absolute three-space location data of an instantaneous state of the body at a point in time and physical space. The detecting comprises identifying the gesture using the gesture data. The navigating comprises translating the gesture to a gesture signal, and navigating through the data space in response to the gesture signal. The data space is a data-representational space comprising a dataset represented in the physical space.

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.

Systems, methods, and computer-readable media are provided for generating computer-mediated reality display data based on user instantaneous motion data. A system includes at least one sensor, a mediated reality data source, and a mediated reality display generator that generates displayable mediated reality scene data based on (a) current reality data of the system from the at least one sensor; (b) mediated reality data from the mediated reality data source; and (c) instantaneous motion data of the system from the at least one sensor. In one example the mediated reality display generator generates the displayable mediated reality scene data by generating displayable mediated reality frame data based on the current reality data and the mediated reality data. The operations further include selecting a portion of the displayable mediated reality frame data as the displayable mediated reality scene data based on the instantaneous motion data. The portion that is selected is offset from a center of the displayable mediated reality frame data and is less than a frame size of the displayable mediated reality frame data and the offset is selected based on said instantaneous motion.

A display apparatus includes: a display unit configured to be able to be curved in an almost cylindrical shape with a surface being oriented outwards and display information in a region of one of an entire periphery and a part of the surface; a viewing intention detector configured to detect viewing intention of a user for the information displayed on the display unit, the user wearing the display unit on a part of a body; a display region determiner configured to determine, according to the viewing intention of the user, a region of the display unit, which is viewable by the user, as a display region for displaying the information; and a display control unit configured to control display of the information in the display region.

A mobile terminal and a control method therefor are disclosed. The mobile terminal includes a body, an input unit configured to receive user input, a display coupled to the body to vary a display region viewed from a front face of the body according to switching between an enlarged display mode and a reduced display mode, and a controller. The controller controls output of at least one application on the display in the enlarged display mode, and controls, upon receiving an event, output of an application corresponding to the event in a first region based on a signal for confirming the received event. The first region is an event application region when a preset application is being output in the enlarged display mode and is a main region of the enlarged display mode when the preset application is not being output in the enlarged display mode.

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.

The invention relates to a method for operating an interactive visibility screen on a transparent pane of a pane device, in particular in a motor vehicle. The visibility screen is generated by means of a display unit of the pane device on the pane by pixel-wise fade-in of opaque image points, wherein the image points form a coherent visibility screen area. In the method, an operational action by the user is first detected by means of a detection device, which comprises a selection of a setting range and a movement relative to the pane. Subsequently, an expansion of the visibility screen area at the setting range is set as a function of the detected movement by means of a control device.

In one embodiment, the system may determine an estimated distance of an eye of a user to a display plane of a display. The system may access, from a memory storage, a number of transmission maps characterizing non-uniform transmission characters of the display as measured from a number of pre-determined view positions within a measurement plane. The measurement plane may be separated from the display plane by a known distance. The system may generate a custom transmission map for the estimated distance of the eye based on the transmission maps using light field rendering. The system may determine a custom correction map based on the custom transmission map. The system may adjust an image to be displayed on the display using the custom correction map. The system may display the image adjusted using the custom correction map on the display.