An electronic device is disclosed. The electronic device of the present disclosure includes a light emitting unit for providing image light, and a display unit for reflecting the image light and transmitting the reflected image light to eyes of a user. The display unit includes a lens unit and a reflective surface for reflecting the image light. The reflective surface is formed of a 3-dimensional curved surface having different curvatures in a first direction and in a second direction perpendicular to the first direction, thereby correcting astigmatism. An electronic device according to the present invention may be associated with an artificial intelligence module, robot, augmented reality (AR) device, virtual reality (VR) device, and device related to 5G services.

An optical system includes a picture generation unit configured to output an optical image, a correcting optical element, and a combiner. The shape of the combiner and the shape of the correcting optical element are correlated such that the optical system can produce augmented reality at relatively long distances (e.g., 1.5 meters or more). The correcting optical element includes a convex reflective surface configured to reflect the optical image output by the picture generation unit. The combiner has a concave reflective surface and a convex transparent surface. The concave reflective surface of the combiner is configured to reflect the optical image reflected by the correcting optical element toward an eye box, which represents an eye pupil of the observer. The convex transparent surface of the combiner is configured to permit external light to pass through the combiner and combine with the optical image reflected by the correcting optical element.

A display system which controls a display of display content, includes: a processor; and a memory having stored thereon instructions executable by the processor. The instructions include: performing image correction processing involving a change in a display position of the display content based on image correction data stored in advance; detecting an attitude change amount of a moving body; calculating a vibration correction amount of the display position of the display content based on the attitude change amount of the moving body; switching an order of processing between image correction processing involving a change in the display position of the display content and vibration correction processing of correcting the display position of the display content based on the vibration correction amount; and controlling the display position of the display content by performing the image correction processing and the vibration correction processing based on the order of the processing.

This document relates to an optical device that uses adaptive optics as part of an optical system. The adaptive optics can be used to correct light rays that correspond to a portion of an eye box based on information received from an eye-tracking unit, and can also correct for aberrations in the optics in the optical device. The adaptive optics include corrective elements that can be modified using modifying elements to correct the angle of light rays, such that rays associated with a specific pupil position and gaze direction of a user's eye can be made parallel and ensure a high quality image is viewed by the user.

A see-through display device includes an image generator configured to emit image light, a combiner which is arranged off-axis with respect to the image light and is configured to generate an off-axis aberration with respect to the image light, and a free-form optical element which is disposed on an optical path of the image light between the image generator and the combiner and is configured to generate a correction aberration with respect to the image light, the correction aberration being opposite to the off-axis aberration.

In one embodiment, a computing system may render an image to be output by a display which sequentially outputs pixel rows of the image at a row-to-row velocity. The system may predict, based on eye-tracking data, an eye-motion velocity within a timeframe for displaying the image. The system may determine a predicted retina projection displacement for each pixel row based on the row-to-row velocity and eye-motion velocity. The system may determine a first correction displacement for each pixel row based on the predicted retina projection displacement. The system may determine a cumulative correction displacement based on the first correction displacement. The system may determine, for each pixel row, a second correction displacement based on the first correction displacement of that pixel row and the cumulative correction displacement. The system may warp each pixel row using the associated second correction displacement and output the warped pixel rows using the display.

Disclosed herein is an image processing apparatus including: a captured image acquisition unit configured to acquire data of a captured image; a correction unit configured to refer to a displacement vector map, which is stored in a storage unit and represents, on an image plane, displacement vectors each representative of a displacement amount and a displacement direction of a pixel used when the captured image is to be corrected to a display image or calculate the displacement vectors to correct the captured image; and an image display controlling unit configured to cause the corrected image to be displayed on a display panel.

The invention relates to a head-up display device, a vehicle comprising such device and a method of forming an image in a head-up display device. The head-up display device is adapted to project an image on an image surface, such as a windshield. The device comprises a waveguide capable of guiding light carrying the image to be displayed, and an optical correction element. According to the invention, the waveguide is configured to couple light propagating therein towards the optical correction element, and the optical correction element is further configured to perform an optical function for said light and to direct the light towards the image surface through the waveguide.

A distortion profile is based on user lens data and a selected optical-mechanical profile of a selected head mounted device. The user lens data is associated with prescription lenses worn by the user. A prescription optical layer is fabricated based on the distortion profile for the selected head mounted device.

The purpose of the present invention is to provide a head-up display having enhanced evenness of display image luminance. This head-up display is provided with: a backlight unit having a light source, the backlight unit emitting illumination light; a liquid crystal display element for displaying an image, the image being irradiated by the illumination light, whereby the liquid crystal display element emits display light; a control means for controlling the illuminance of the backlight unit and display by the liquid crystal display element; a housing having an opening through which the display light passes, the housing housing the liquid crystal display element and the backlight unit; and a cover glass for reflecting and/or transmitting in at least one location in a display light path and projecting the reflected and/or transmitted display light.