A head-up display system for a vehicle includes a head-up display apparatus and an occupant monitoring apparatus. The head-up display apparatus includes a projection device configured to project a three-dimensional image in front of an occupant of the vehicle. The head-up display apparatus is configured to project a projection image with respect to an object present outside of the vehicle. The occupant monitoring apparatus includes an imaging device configured to capture an image of the occupant. The occupant monitoring apparatus is configured to generate personal data related to a sense of sight of the occupant on the basis of the captured image of the occupant. The head-up display apparatus is configured to adjust the projection image in the three-dimensional image on the basis of the personal data generated by the occupant monitoring apparatus, and project, from the projection device, the three-dimensional image in which the projection image is adjusted.

A stereoscopic display apparatus is disclosed. In the stereoscopic display apparatus, each unit pixel of a display panel includes a first transparent region. A barrier panel on the display panel may include second transparent regions overlapping with the first transparent region of each unit pixel. Thus, in the stereoscopic display apparatus, the transparency may be improved without the quality deterioration of a stereoscopic image.

A stereoscopic display apparatus is disclosed. In the stereoscopic display apparatus, each unit pixel of a display panel includes a first transparent region. A barrier panel on the display panel may include second transparent regions overlapping with the first transparent region of each unit pixel. Thus, in the stereoscopic display apparatus, the transparency may be improved without the quality deterioration of a stereoscopic image.

When a predetermined image is displayed for a user such that the user is able to visually recognize the image, the user sight line direction is detected, a part assumed to be present in the detected user sight line direction is set to a first image, an image complementary to the first image for the predetermined image is set to a second image, the positions of the retinas of the eyes of the user are scanned with laser light from a retinal scanning display unit fitted to the head of the user and the first image is focused on a position away from the position of the eyes of the user by a first distance and is displayed. The second image is displayed on the surface of the panel of a panel display unit in a position away from the user by a second distance shorter than the first.

An electronic display includes a display panel that operates in a single display mode to provide a single display, or a dual display mode to provide two displays separated by an inactive region. The electronic display includes the display panel and a panel driver. The display panel includes a left pixel region, a right pixel region, and a middle pixel region between the left and right pixel regions. In the single display mode of the electronic display, the panel driver provides first gate signals generated from first input data to the left, right, and middle pixel regions. In a dual display mode, the panel driver provides second gate signals generated from second input data to the left and right pixel regions. The first input data has a first resolution that is larger than a second resolution of the second input data.

A head-mounted device includes a first device portion and a second device portion. A first coupler portion of the first device portion is connectable to a second coupler portion of the second device portion to define a connected position in which the first device portion is connected to the second device portion and a disconnected position in which the first device portion is disconnected from the second device portion. A second adjuster portion of the second device portion causes a first adjuster portion of the first device portion to move a first optical module and a second optical module in response to movement of the first device portion and the second device portion from the disconnected position to the connected position.

A head-mounted device includes a first device portion and a second device portion. A first coupler portion of the first device portion is connectable to a second coupler portion of the second device portion to define a connected position in which the first device portion is connected to the second device portion and a disconnected position in which the first device portion is disconnected from the second device portion. A second adjuster portion of the second device portion causes a first adjuster portion of the first device portion to move a first optical module and a second optical module in response to movement of the first device portion and the second device portion from the disconnected position to the connected position.

An electronic device and method are disclosed. The electronic device includes a first camera configured to capture a frontal external environment of the electronic device, a second camera oriented opposite to the first camera and configured to capture gaze directions of a user's left eye and right eye, a first display panel corresponding to the left eye, a second display panel corresponding to the right eye, a memory, and a processor that implements the method, including: identifying, using the second camera, a dominant eye and a non-dominant eye among the left eye and right eye, identifying a dominant display panel from among the first and second display panels corresponding to the dominant eye, and a non-dominant display panel from among the first and second display panels corresponding to the non-dominant eye, and changing settings of the dominant display panel to be different from settings of the non-dominant display panel.

A method of super-resolution image processing. The method includes inputting first image data representative of a first version of at least part of an image with a first resolution to a machine learning system. The first image data includes pixel intensity data representative of an intensity value of at least one color channel of a pixel of the first version of the at least part of the image, and feature data representative of a value of at least one non-intensity feature associated with the pixel. The first image data is processed using the machine learning system to generate second image data representative of a second version of the at least part of the image with a second resolution greater than the first resolution.

An electronic device is disclosed. The electronic device includes: a window; a display disposed in a first direction of the window; a housing including a first surface and a second surface extended from the first surface toward the window; a first film layer disposed on an inner surface of the housing and including: a first area that overlaps at least a portion of the first surface and is substantially transparent or translucent; and a second area that is extended from an edge of the first area along the second surface, and is substantially opaque; and a second film layer disposed on the first film layer in a second direction opposite to the first direction, the second film layer overlapping an entirety of the first area of the first film layer and overlapping a portion of the second area. Other embodiments are possible.