Disclosed is an electronic apparatus. The electronic apparatus includes a processor configured to obtain first upscaling information of an input image using an artificial intelligence (AI) model that is trained to obtain upscaling information of an image. The processor is also configured to downscale the input image based on the obtained first upscaling information, and obtain an output image by upscaling the downscaled image based on an output resolution.

Disclosed are systems, methods, and non-transitory computer-readable media for adjusting depth of AR content on HUD. A viewing device identifies, based on sensor data, a physical object visible through a transparent display of the vehicle. The sensor data indicates an initial distance of the physical object from the vehicle. The viewing device gathers virtual content corresponding to the physical object and generates an initial presentation of the virtual content based on the initial distance. The viewing device presents the initial presentation of the virtual content on the transparent display at a position on the transparent display corresponding to the physical object. The viewing device determines, based on updated sensor data, an updated distance of the physical object and generates an updated presentation of the virtual content based on the updated distance. The viewing device presents the updated presentation of the virtual content on the transparent display of the vehicle.

Methods and apparatus for systems using a scene codec are described, where systems are either providers or consumers of multi-way, just-in-time, only-as-needed scene data including subscenes and subscene increments. An example system using a scene codec comprises aplenoptic scene database containing one or more digital models of scenes, where representations and organization of representations are distributable across multiple systems such that collectively the multiplicity of systems can represent scenes of almost unlimited detail. The system may further include highly efficient means for the processing of these representation and organizations of representation providing the just-in-time, only-as-needed subscenes and scene increments necessary for ensuring a maximally continuous user experience enabled by a minimal amount of newly provided scene information, where the highly efficient means include a spatial processing unit.

The present disclosure provides a terminal control method, apparatus, and system. The control method includes: generating an orchestration plan according to a program selected by a user; selecting, according to the program and the orchestration plan, from tiling screens that form a terminal, multiple tiling screens used for displaying the program; segmenting, according to the selected multiple tiling screens, a multimedia resource corresponding to the program to obtain segmented multimedia resources; and sending said multimedia resources to the multiple tiling screens, so that each tiling screen displays according to the corresponding multimedia resource and the orchestration plan.

A method for displaying a display element on at least one vehicle-side display device of a vehicle includes: transmitting, from the vehicle to a terminal via a data link, information about a size of the vehicle-side display device; providing, by the terminal, data for displaying the display element, as a function of the transmitted information about the size of the display device; and transmitting, from the terminal to the vehicle via the data link, the data for displaying the display element.

A high-definition image is preprocessed to generate a substantially losslessly-reconstructable set of image components that include a relatively low-resolution base image and a plurality of extra-data images that provide for progressively substantially losslessly reconstructing the high-definition image from the base image, wherein a single primary-color component of the extra-data images provides for relatively quickly reconstructing full-resolution intermediate images during the substantially lossless-reconstruction process.

A high-definition image is preprocessed to generate a substantially losslessly-reconstructable set of image components that include a relatively low-resolution base image and a plurality of extra-data images that provide for progressively substantially losslessly reconstructing the high-definition image from the base image, wherein a single primary-color component of the extra-data images provides for relatively quickly reconstructing full-resolution intermediate images during the substantially lossless-reconstruction process.

Systems, apparatuses, and methods for using a multi-stream foveal display transport layer are disclosed. A virtual reality (VR) system includes a transmitter sending a plurality of streams over a display transport layer to a receiver coupled to a display. Each stream corresponds to a different image to be blended together by the receiver. The images include at least a foveal region image corresponding to a gaze direction of the eye and a background image which is a lower-resolution image with a wider field of view than the foveal region image. The phase timing of the foveal region stream being sent over the transport layer is adjusted with respect to the background stream to correspond to the location of the foveal region within the overall image. This helps to reduce the amount of buffering needed at the receiver for blending the images together to create a final image to be driven to the display.

A system and method provides a video chat capability where the video portion of the chat is initially impaired, but gets progressively clearer, either as time elapses, or as the users speak or participate with relevant information.

This invention belongs to the microscopic imaging technology category. This intention provides a microscopic imaging of the method and apparatus. The microscopic imaging method includes: illuminating the sample with illumination radiation to stimulate the detection radiation; capturing the detection radiation from the sample; capturing the s, with the intensity data of the detection radiation from the sample; applying the calibration algorithm to the captured image(s) to acquire the processed second image; the resolution of the processed second image is higher than the acquired first image. The apparatus for microscopic imaging is configured to be able to perform the method. This invention is able to obtain higher resolution images, and can be suitable for fast dynamic super-resolution microscopic imaging.