An image processing apparatus includes: an acquisition unit configured to acquire a captured image of 1 frame as an Nth frame image; and a control unit configured to (1) record the Nth frame image in a memory, (2) enlarge an region having a predetermined aspect ratio in a horizontal direction wherein the region is a part of an image of a frame prior to the Nth frame recorded in the memory, and (3) display the enlarged region, within a period in which the Nth frame image is acquired and recorded.

A camera system captures an image in a source aspect ratio and applies a transformation to the input image to scale and warp the input image to generate an output image having a target aspect ratio different than the source aspect ratio. The output image has the same field of view as the input image, maintains image resolution, and limits distortion to levels that do not substantially affect the viewing experience. In one embodiment, the output image is non-linearly warped relative to the input image such that a distortion in the output image relative to the input image is greater in a corner region of the output image than a center region of the output image.

Disclosed is a display apparatus. When image data is received, a position of a clipping box is adjusted according to a position of a target object in the image data; and an adjusted image is output to a second chip, the adjusted image is a portion of the image data in the adjusted clipping box, and the second chip is configured to receive the adjusted image output from an image processor and output the adjusted image to a display.

Systems and methods are provided for displaying a first portion of a video, the first portion comprising a subset of the video that fits in a display area of a computing device. The systems and methods further detect movement of the computing device during playback of the first portion of the video, calculate a rotation of the display of the first portion of the video based on a direction of the movement, and cause the display of the first portion of the video to rotate relative to the direction of movement to display a second portion of the video, the second portion comprising a subset of the video that is associated with the direction of movement and that was at least partially not visible in the first portion of the video when displayed in the display area of the computing device.

A camera system captures an image in a source aspect ratio and applies a transformation to the input image to scale and warp the input image to generate an output image having a target aspect ratio different than the source aspect ratio. The output image has the same field of view as the input image, maintains image resolution, and limits distortion to levels that do not substantially affect the viewing experience. In one embodiment, the output image is non-linearly warped relative to the input image such that a distortion in the output image relative to the input image is greater in a corner region of the output image than a center region of the output image.

A device displays, in a first display region of a camera user interface, a first live view from a first camera. While displaying the first live view from the first camera, the device detects movement of a first user input (e.g., a first contact on a touch-sensitive surface). In accordance with a determination that the movement of the first user input meets first movement criteria, the device moves the first live view in the first display region in accordance with the movement of the first user input, displays a second live view from a second camera, and moves the second live view in the first display region in accordance with the movement of the first user input.

The disclosure provides a video transmission method for virtual reality. The method includes reorganizing a first video and a second video obtained to generate a third video suitable for transmission through a physical wire, hence avoiding distortion caused by compression of a high-definition video. The disclosure further includes a video processing device and a video generating system employing the video transmission method.

A device displays a camera user interface for recording media images in a plurality of media recording modes. While displaying the camera user interface, the device captures media with one or more cameras. In response to capturing the media, in accordance with a determination that the captured media is consistent with a first media recording mode, the device displays a first prompt in the camera user interface that prompts a user to take one or more actions associated with the first media recording mode; and in accordance with a determination that the captured media is consistent with a second media recording mode, the device displays a second prompt in the camera user interface that prompts the user to take one or more actions associated with the second media recording mode, where the first media recording mode is different from the second media recording mode.

Described are methods, systems, and computer-readable media to automatically crop videos using personalized parameters. Some implementations include a computer-implemented method that comprises obtaining an input video, determining a per-frame crop score for one or more candidate crop regions in each frame of the input video, generating a face signal for the one or more candidate crop regions, adjusting each per-frame crop score based on the face signal, determining a minimal cost path that represents crop region locations based on motion cost and the adjusted per-frame crop score, generating crop keyframing corresponding to the crop region locations along the minimal cost path, wherein the crop keyframing includes a start frame, an end frame, and crop region location, and outputting a modified video that has one or more of an output aspect ratio or an output orientation that is different than a corresponding aspect ratio or an orientation of the input video.

Conversion components may receive game video rendered in high-dynamic-range (HDR) and standard-dynamic-range (SDR) camera video of a game player. The conversion components may provide local video output to a local display and remote video output for network transmission to remote viewers. The SDR camera video may be converted to HDR and provided with HDR game video in the local video output. For HDR network transmission, the HDR game video and converted HDR camera video may be included in the remote video output. For SDR network transmission, the HDR game video may be converted to SDR and provided with the SDR camera video in the remote video output. The game video, camera video and other video feeds may have respective portals in the local and remote video outputs. The local and remote video outputs may have respective visual portal arrangements that may be at least partially different from one another.