The present disclosure provides a device for stereoscopic displaying and a method for controlling the same. The device for stereoscopic displaying comprises: a rotary shaft and at least one display assembly. The display assembly is fixed to the rotary shaft, the display assembly comprises at least three display surfaces, and at least one of the display surfaces is arranged opposite to the rotary shaft in a radial direction of the rotary shaft.

In some implementations, a user device can coordinate adjustments to a composite GUI generated in cooperation with an accessory device that presents the composite graphical user interface. For example, the user device can receive configuration data that defines the maximum GUI display area (e.g., size, dimensions) of the accessory device, various view areas within the GUI display area of the accessory device into which the user device can render GUIs, and/or transitions between the various view areas. The user device can generate a display buffer based on the maximum GUI display area, generate a graphical user interface in an area of the buffer corresponding to a current view area specified by the accessory device, and send to the accessory device video frames corresponding to the display buffer. The accessory device can generate a composite GUI based on the received video frames that include the user device generated GUI.

The embodiments of the disclosure provide a method for mitigating dizziness, an electronic device, and a computer readable medium. The method includes: providing a first visual content of a first reality mode in a field of view; and adding a specific mask to the first visual content, wherein the specific mask shows a specific part of a second visual content of a second reality mode, and a location of the specific mask in the first visual content is fixed.

A position within displayed digital content that a user is ocularly focused on (e.g., where within displayed content the user is looking) may be determined. Digital content comprising a visual indication of the position may be rendered. The visual indication of the position may be displayed on the same display that the user is looking at and/or a different display. In some embodiments, the position may be determined based on data generated by a sensor physically attached to the user. Additionally or alternatively, the position may be determined based on data generated by a stationary computing device comprising a sensor configured to track changes in ocular position of the user. In some embodiments the digital content may comprise digital images and/or video (e.g., broadcast content, on-demand content, images and/or video associated with a computer application, or the like).

Systems and methods of use are presented that resize a displayed program presentation based on a requested television size, which allows a single large display monitor (television) to act as a proxy of all the smaller television sizes available in a given model line of televisions. The resized program is presented on the display monitor with a physical size larger than the requested size. Pricing information for the requested television size is superimposed on the presented resized program. Outlines for intermediate sizes of televisions of the same make and model to that of the display monitor are also presented in the presented program, including size and price indicators for the intermediate sizes. Multiple display monitors, each having a separate media player, can be implemented in a retail environment so as to allow several makes and models to be compared. Sync signals keep video transmitted by the media players synchronized.

Systems and methods for generating multi-monitor recommendations. In some embodiments, an Information Handling System (IHS) may include: a processor and a memory coupled to the processor, the memory having program instructions stored thereon that, upon execution, cause the IHS to: collect window information during use of the IHS; and create a multi-monitor recommendation based, at least in part, upon the window information.

An autonomous mobile outdoor ground treatment robot includes an at least upper-side outer contour and a display screen device. The at least upper-side outer contour includes a contour face in a plan view of the outdoor ground treatment robot. The display screen device comprises a display screen face. The size of the display screen face in plan view of the outdoor ground treatment robot is at least 5% of a size of the contour face.

An electronic device and method are disclosed. The electronic device includes a first camera; a first display panel including multiple pixels and disposed to overlap the first camera, in at least a partial region thereof; and a processor. The processor implements the method, including: displaying, on a first display panel, a graphic user interface; activating, via at least one processor, a first camera, wherein the first display panel includes multiple pixels, and is disposed to overlap the first camera in at least a partial region thereof; deactivating, via the at least one processor, at least one pixel disposed within a first region of the first display panel, wherein the first region is included in the partial region; and changing the graphic user interface to be displayed at least in part to a second region of the first display panel, wherein the second region is in contact with the first region.

A handheld imaging device has a data receiver that is configured to receive reference encoded image data. The data includes reference code values, which are encoded by an external coding system. The reference code values represent reference gray levels, which are being selected using a reference grayscale display function that is based on perceptual non-linearity of human vision adapted at different light levels to spatial frequencies. The imaging device also has a data converter that is configured to access a code mapping between the reference code values and device-specific code values of the imaging device. The device-specific code values are configured to produce gray levels that are specific to the imaging device. Based on the code mapping, the data converter is configured to transcode the reference encoded image data into device-specific image data, which is encoded with the device-specific code values.

An electronic device may have a flexible display. The electronic device may have housing portions that are rotatably coupled to each other so that the flexible display may fold along one or more bend axes. A device may have rollers that store a flexible display and that help deploy the display from within a housing when additional display area is desired. A touch screen in a housing may be overlapped by a flexible display that has been scrolled outwardly from the housing. Wireless transmitter and receiver circuitry may be used to convey image data to display driver circuitry. The display driver circuitry may display images on a pixel array in a flexible display based on the image data. Magnets may be used to outwardly bias edge-mounted bistable support structures to help prevent a rolled flexible display from wrinkling.