A head up display apparatus includes: an image display apparatus having a light source and a display element and forming an image; an image-light projecting means displaying a virtual image onto a forward part of a vehicle by projecting the image light emitted from the image display apparatus to be reflected on a windshield 3; and a point-of-view detecting system 6 sensing a point of view of the driver. In the head up display apparatus, the image-light projecting means includes a means generating illumination light entirely made of single-color visible light emitted to a face of the driver in a predetermined state of the vehicle.

According to an example, a system for electronic display illumination comprises a display, a sensor communicatively coupled to the display to detect a user and a user eye gaze, and a processing resource communicatively coupled to the sensor. In some examples, the processing resource may determine an active screen area and an inactive screen area of the display based on the user eye gaze; instruct a display controller to adjust a display value of the inactive screen area; and transmit active screen area data to a secondary display.

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.

Systems and methods are disclosed for adjustable polarization in service-providing terminals. In some embodiments, a system is disclosed that includes a display, an input device, an adjustable polarization screen adjacent to the display, and a polarization adjuster. The system may further include a processor configured to execute instructions to perform operations comprising providing illumination to the adjustable polarization screen through the display, controlling, via the polarization adjuster, a polarization of the adjustable polarization screen to a first polarization, receiving, via the input device, a polarization selection input, and, based on the polarization selection input, adjusting, via the polarization adjuster, the polarization of the adjustable polarization screen from the first polarization to a second polarization.

A display case includes a transparent LCD panel for viewing display case contents therethrough.

The present application provides a GOA circuit and a display panel. In the GOA circuit, one of two GOA units of a same stage in GOA sub circuits at left and right sides of the display panel is deployed only with an all-on module and the other one of the two GOA units is deployed only with an all-off module. In such a way, both the number of the all-on modules and the number of the all-off modules required in the GOA unit are halved, thereby reducing the area occupied by the GOA circuit. It is beneficial for realizing a display panel with a narrow bezel.

A wearable terminal device capable of wirelessly communicating with a mobile terminal device having a display unit, the wearable terminal device comprising receiving status information of the mobile terminal device from the mobile terminal device when status of the mobile terminal device changes, determining whether or not to select display of the wearable terminal device based on the status information, and controlling the display of the wearable terminal device based on a determination result by the determining.

A user interface device includes: an output device having an output region predefined around an output unit; an acquisition unit acquiring information about a user's gesture performed around the output region; and a controller determining an area of a shielded region which is shielded by the user's gesture in the output region based on the acquired information and controlling output of the output device.

A standby power controller (SPC) supplies power to an appliance such as a television, and cuts power to the appliance if the appliance is going unused. The SPC includes first and second sensors, each detecting a type of user activity (such as user presence and remote control usage), and a switch which controls power to the appliance in dependence on the detection status of the first and second sensors, and also preferably in dependence on the prior detection status of at least one of the sensors at one or more points of time in the past.

An electronic device includes a communicator configured to perform communication with an external device, a display configured to display a UI (User Interface) element in a screen, and a processor. The processor receives through the communicator, touch panel information of the external device and first data according to a first input of a user detected on the touch panel of the external device, and changes a location of the UI element displayed on the screen based on the touch panel information and the first data.