An image processing device and an image processing method are provided. The image processing device includes multiple image input units, an expansion module, a controller, and an image processing module. The multiple image input units are configured to receive multiple image signals and convert the multiple image signals into multiple converted image signals. The multiple converted image signals have a first image format. The expansion module is detachably coupled to the multiple image input units and is configured to output selected image signals according to a first selection signal. The controller is configured to provide the first selection signal. The image processing module is configured to receive the selected image signals to integrate into a picture in picture.

Method for displaying super-resolution video of at least one-moving object without image artifacts, including the procedures of acquiring microscanned images of at least one moving object, a first and second subset of the images respectively forming a first and second data set, for each data set, analyzing at least a portion of the sub-set of the images for spatial and temporal information, determining a respective movement indication of the moving object according to the spatial and temporal information, in parallel to the procedure of analyzing, forming a respective super-resolution image from each data set and designating a respective bounded area surrounding the moving object, and repeatedly displaying each super-resolution image outside the bounded area a plurality of times at a video frame rate and displaying during those times within the respective bounded area, a plurality of consecutive microscanned images of the moving object at the video frame rate.

The described technology is directed towards generating a new video image sequence (e.g., for playback at 30 frames per second) based on an existing video image sequence (e.g., originated for playback at 24 frames per second). The technology is based on processing frames, e.g., adjacent pairs of frames in a four-frame sequence, to obtain candidate frames for selecting a similar candidate frame to insert into the original sequence to create the new sequence (e.g., a five-frame sequence). Aspects include selecting a repeated frame to insert or creating a new frame from existing frames to insert, to generate the new sequence based on a difference/scoring comparison.

An approach is provided in which the approach displays a main video feed and multiple secondary video feeds on a display. The multiple secondary video feeds are embedded in the main video feed at multiple locations based on visual characteristics sets of the multiple secondary video feeds. The approach dynamically detects a level of interest of a user at a first one of the locations in the main video feed based on a set of physical characteristics of the user. The approach identifies a first one of secondary video feeds that corresponds to the first location and, in turn, resizes the first secondary video feed based on the detected level of interest.

The present invention provides an apparatus and a method for switching and converting video signals, wherein the method majorly includes the steps of: receiving N number of DisplayPort video signals and N number of USB video signals by N number of USB Type-C connection interfaces which are in compliance with a DisplayPort Alternate Mode specification, and N is a natural number greater than or equal to 2; and selecting one out of the DisplayPort video signals and one out of the USB video signals; converting the selected DisplayPort video signal and the selected USB video signal into a DisplayPort video signal or a HDMI video signal; transmitting the converted DisplayPort video signal or HDMI video signal to Q number of display devices, and Q is a natural number greater than or equal to 2.

The disclosure discloses a method for transmitting image data and an intelligent TV set. The method includes transmitting, by a primary chip, image data to a second chip. The image data comprises pixel data including a pixel type for indicating that a pixel in the image to be displayed is a menu On-Screen Display (OSD) pixel or a video pixel. The method includes receiving, by the second chip, the image data, and determining the pixel type in the image data. The method further includes performing, by the second chip, a Motion Estimate and Motion Compensation (MEMC) function on the pixel in response to the pixel type being the video pixel, and not performing the MEMC function on the pixel in response to the pixel type of the pixel being the menu OSD pixel.

Methods, systems, and devices, including computer programs encoded on computer storage media, for converting video playing mode are provided. One of the methods includes: detecting video content for playing in a browser page; inserting a conversion button in the browser page for converting the playing mode of the video content; and in response to an operation performed by a user on the conversion button, converting the playing mode of the video content between a normal video playing mode and a VR video playing mode.

An digital imaging system and method that is provided that is capable of receiving and processing multiple types of image formats. Thus, the system is capable of receiving image signals from multiple types of image sources, such as medical imaging devices, that may each use different image formats, and converting the image format of the received image signals to the image formats required by one or more predetermined devices, such as an image recording device and a display.

It is desirable to provide a technique capable of further reducing the power consumption of the image capturing device. An image capturing device including: a motion determination unit that determines the presence/absence of motion in a plurality of pixels on the basis of an addition signal of the plurality of pixels to obtain a motion determination result; and a transmission control unit that controls whether or not to transmit image data corresponding to at least the plurality of pixels on the basis of the motion determination result is provided.

A movement detection circuit, a motion estimation circuit and associated movement detection method are provided. The movement detection circuit includes a candidate searching module including a first-frame and a second-frame candidate circuits, an object selection module including a first selection circuit, a second selection circuit, and a motion vector calculation circuit. The first-frame and the second-frame candidate circuits respectively locate a first and a second first-frame candidate positions in the first frame and locates a first and a second second-frame candidate positions in the second frame. The first-frame object selection circuit identifies one of the first and the second first-frame candidate positions as a first-frame object position, and the second-frame object selection circuit identifies one of the first and the second second-frame candidate positions as a second-frame object position. An object motion vector representing movement of an object based on the first-frame and the second-frame object positions is calculated.