Methods, systems, apparatuses, and computer-readable media are provided for initiating location-driven sensory prompts reflecting changes to virtual objects. In one implementation, the computer-readable medium includes instructions to cause a processor to enable interaction with a virtual object located in an extended reality environment associated with a wearable extended reality appliance; receive data reflecting a change associated with the virtual object; determine whether the virtual object is within or outside a field of view of the wearable extended reality appliance; cause initiating of a first sensory prompt indicative of the change when the virtual object is determined to be within the field of view; and cause initiating of a second sensory prompt indicative of the change when the virtual object is determined to be outside the field of view, the second sensory prompt differing from the first sensory prompt.

A system and method for generating videos of individuals interacting with virtual objects. A wearable extended reality appliance generates an extended reality environment including at least one virtual object. First image data reflects a first perspective of an individual wearing the wearable extended reality appliance, including physical hand movements interacting with the at least one virtual object from the first perspective. Second image data reflects a second perspective facing the individual, including second physical hand movements interacting with a virtual object from the second perspective. The first image data and the second image data are analyzed to determine an interaction with the virtual object. The rendered representation of the virtual object from the second perspective is melded with the second image data to generate a video of the individual interacting with the virtual object from the second perspective.

The display control ECU changes the display color of the content in accordance with the display content of the content when displaying the content at a position where the windshield glass of the vehicle is located by the AR glass. Further, when the display color of the content is other than white, the display control ECU sets the display luminance of the border of the content to a second predetermined value or more or sets the brightness of the border of the content to a third predetermined value or more. The display control unit, when the color of the display of the content is white, the display luminance of the border of the content is less than the second predetermined value or is larger than the second predetermined value fourth predetermined value, or the brightness of the border of the content is less than the third predetermined value.

A method, system, apparatus, and/or device for displaying a portion of data so as to not obstruct a portion of a central visual field. The method, system, apparatus, and/or device may include a display configured to display data and a processing device coupled to the display. The processing device may be configured to determine a position of an eye of a viewer with respect to the display, define a first region of the display substantially corresponding with a peripheral vision field of the eye, define a second region of the display substantially corresponding with a central visual field of the eye, send a first portion of the data to be displayed at the first region, and send a second portion of the data to be displayed at the second output region such that a portion of the central visual field is unobstructed by the second portion of the data.

A video encoding and decoding system that implements an adaptive transfer function method internally within the codec for signal representation. A focus dynamic range representing an effective dynamic range of the human visual system may be dynamically determined for each scene, sequence, frame, or region of input video. The video data may be cropped and quantized into the bit depth of the codec according to a transfer function for encoding within the codec. The transfer function may be the same as the transfer function of the input video data or may be a transfer function internal to the codec. The encoded video data may be decoded and expanded into the dynamic range of display(s). The adaptive transfer function method enables the codec to use fewer bits for the internal representation of the signal while still representing the entire dynamic range of the signal in output.

The present invention relates to a display device which changes the quality of displayed images in real time according to the genres of the images, the display device comprising: a storage unit which stores picture quality according to the genres of images; a display unit which displays an image corresponding to an input image signal; and a control unit which acquires the genre of an image and changes the quality of the image to the picture quality corresponding to the genre.

Methods and systems are disclosed for performing operations for displaying virtual content on a contact lens. The operations comprise causing the contact lens to operate in a first display mode to allow unobstructed light associated with a real-world environment to be received by a pupil of a user; detecting a condition associated with display of virtual content; selecting between a second display mode and a third display mode as a new display mode in which to operate the contact lens, the second display mode obstructing a portion of the light associated with a real-world environment received by the pupil with the virtual content, the third display mode obstructing all of the light associated with a real-world environment received by the pupil with the virtual content; and transitioning the contact lens from operating in the first display mode to operating in the new display mode in response to detecting the condition.

According to an example embodiment of the present disclosure, an electronic device includes a display that is flexible, has at least a portion located at a first side of the electronic device, and is changeable in size to which the display is exposed to the first side, and a controller, wherein the controller is configured to display content related to a first application in at least a portion of the display exposed to the first side, identify an event that the display exposed to the first side is expanded in size, and display content related to a second application corresponding to the first application in at least a portion of the expanded display.

Controlling a display in an augmented reality head-up display for a vehicle. At least one safety-relevant parameter is determined in a first step. If two or more safety-relevant parameters are determined, one of the determined parameters can optionally be selected as a critical parameter. The intensity of the display element displayed on the augmented reality head-up display is subsequently adjusted on the basis of the at least one safety-relevant parameter. The display element is then output for display on the augmented reality head-up display.

Systems, methods, and non-transitory computer readable media including instructions for performing duty cycle control operations for a wearable extended reality appliance are disclosed. Performing the duty cycle control operations includes receiving data representing virtual content in an extended reality environment associated with a wearable extended reality appliance; identifying in the extended reality environment a first display region and a second display region separated from the first display region; determining a first duty cycle configuration for the first display region; determining a second duty cycle configuration for the second display region, wherein the second duty cycle configuration differs from the first duty cycle configuration; and causing the wearable extended reality appliance to display the virtual content in accordance with the determined first duty cycle configuration for the first display region and the determined second duty cycle configuration for the second display region.