A display apparatus comprises a mirror assembly, a first mirror of the mirror assembly oscillating about a first axis upon excitation by a first excitation signal and the first or a second mirror of the mirror assembly oscillating about a second axis upon excitation by a second excitation signal, a light source projecting a light beam onto the mirror assembly for deflection by the mirror assembly towards an image area, the light source being controlled according to pixels of image frames, a gaze tracker detecting a user's region of interest, ROI, within the image area, and a controller modulating one of the excitation signals by a first modulation signal which is dependent on the ROI detected by the gaze tracker.

A system may monitor an appendage gesture with a smart device, extrapolate a gesture direction, select an item on a display based on the gesture direction, and display the item on a second display on the smart device.

A display device, includes: a scan driver configured to sequentially supply scan signals having a turn-on level to the first scan line and the second scan line during a first period and to concurrently supply scan signals having a turn-on level to the first scan line and the second scan line during a second period after the first period, wherein: a mask period corresponds to a difference between a start point of the second period and a start point of the first period in a next frame period, a first frame period and a second frame period have different mask periods, a third frame period between the first frame period and the second frame period has a same mask period as the first frame period, and a fourth frame period between the first frame period and the second frame period has a same mask period as the second frame period.

A system includes a display, and a central programming unit, wherein the central programming unit is configured to automatically adjust a brightness of the display based on factors of the environment surrounding the display.

A vehicle includes a driver sensor provided inside the vehicle and configured to obtain a face image of a driver; a side camera configured to obtain images of a rear left side and a rear right side of the vehicle; a display configured to output the images of the rear left side and the rear right side of the vehicle; and a controller electrically connected to the driver sensor, the side camera, and the display; wherein the controller is configured to identify a gaze direction of the driver based on the face image of the driver, and adjust at least one of a frame rate of the side camera or a screen brightness of the display based on the gaze direction of the driver.

A display device includes a display panel which displays an image, and a panel driving block which receives a control signal and generating a criterion point signal including information about a criterion point for adjusting luminance of the image based on the control signal. The panel driving block receives image signals, generates a correction value based on distance information about a location of the display panel, at which each of the image signals is displayed, and the criterion point, and generates correction image signals by converting the image signals based on the correction value.

Disclosed are systems and methods for adaptively adjusting brightness of a wearable device projection system. The systems and methods perform operations comprising: causing projection elements of the AR wearable device to project an image; receiving a measure of ambient light from an ambient light sensor; adjusting one or more hardware parameters of the projection elements of the AR wearable device based on the measure of ambient light; modifying one or more color values of the image displayed by the projection elements of the AR wearable device based on the measure of ambient light; and projecting the image with the modified color values using the projection elements of the AR wearable device with the adjusted one or more hardware parameters.

An electronic apparatus includes a processing unit, a memory, a processor, and an operation control unit. The processing unit executes system processing based on a system. The memory temporarily stores image data of an image captured by an imaging device. The processor processes image data stored in the memory. The operation control unit controls an operating state of the system. The processor includes a face detection unit that processes image data of an image obtained by the imaging device capturing a predetermined imaging range and stored in the memory to perform detection of a face area with a face captured therein and an orientation of the face from the image. The operation control unit controls, according to a detection result by the face detection unit, the operating state of the system to be a first operating state or a second operating state.

Systems, apparatuses, and methods may provide for technology to dynamically control a display in response to ocular characteristic measurements of at least one eye of a user.

A head-mounted display device includes a mounting portion configured to be attached to a head of a user, an image display unit disposed in the mounting portion and configured to display an image to be visually recognized by the user, a state detection unit configured to detect a first state in which the mounting portion is attached to the head and a second state in which the mounting portion is detached from the head, and a display control unit configured to cause the image display unit to stop displaying an image when the state detection unit detects the second state.