An image capturing apparatus includes a capture part acquiring image data, and a display displaying an image on a display based on the image data. First information acquired includes at least either an azimuth angle or an elevation angle as a direction of the image and at least either an angle of view of the image or angle-of-view related information calculating the angle of view. When a second direction of a second image is included within a range of a first angle of view in a first direction of a first image, the second image is associated with the first image, and the first image is displayed within the display, and display is performed in a state in which the second image to be associated with the first image is overlapped on the first image within the display as the second image or second information indicating the second image.

There is provided an image processing apparatus including a display image generation section configured to generate display image data by performing a display projection process in a case where panorama image data to be a display target is judged to be a full circumference panorama image.

There is provided an image processing apparatus including a display image generation section configured to generate display image data by performing a display projection process in a case where panorama image data to be a display target is judged to be a full circumference panorama image.

A vehicular rear backup system includes a rear backup digital camera disposed at a vehicle and a display device having a video display screen disposed in an interior cabin of the vehicle and viewable by the driver of the vehicle. Rear backup video images that are derived from image data captured by the rear backup digital camera are displayed on the video display screen no later than two seconds after the driver of the vehicle first changes propulsion of the vehicle during a new ignition cycle to reverse mode to commence a first backup event. Until the first backup event is completed, the video display screen displays rear backup video images. During a backup event of the vehicle, image data captured by the rear backup digital camera is provided to and is processed by an image processor of the system to detect presence of an object rearward of the vehicle.

A vehicular rear backup system includes a rear backup digital camera disposed at a vehicle and a display device having a video display screen disposed in an interior cabin of the vehicle and viewable by the driver of the vehicle. Rear backup video images that are derived from image data captured by the rear backup digital camera are displayed on the video display screen no later than two seconds after the driver of the vehicle first changes propulsion of the vehicle during a new ignition cycle to reverse mode to commence a first backup event. Until the first backup event is completed, the video display screen displays rear backup video images. During a backup event of the vehicle, image data captured by the rear backup digital camera is provided to and is processed by an image processor of the system to detect presence of an object rearward of the vehicle.

The disclosure relates to a method of delivering a video frame. One implementation may involve spatially partitioning a video frame into a plurality of blocks, encoding at least one of the plurality of blocks of the video frame, and transmitting the at least one of the plurality of blocks of the video frame.

The disclosure relates to a method of delivering a video frame. One implementation may involve spatially partitioning a video frame into a plurality of blocks, encoding at least one of the plurality of blocks of the video frame, and transmitting the at least one of the plurality of blocks of the video frame.

A video stream processing method, a device, a terminal device, and a computer-readable storage medium are provided, including steps for acquiring a first video stream through a first camera and acquiring a second video stream through a second camera in response to receiving a slow-motion shooting instruction, the slow-motion shooting instruction carrying a frame rate of a slow-motion video stream; encoding the first video stream and the second video stream into a third video stream with a third frame rate, the third frame rate being greater than the first frame rate, and the third frame rate being greater than the second frame rate; and acquiring a fourth video stream with a fourth frame rate through performing a frame interpolation algorithm on the third video stream, the fourth frame rate being the same as the frame rate of the slow-motion video stream.

A view system for a vehicle (1) with a tractor (2) and a trailer (3). The view system has a capture unit (10) with an image sensor (12) for capturing image data of an area of view, around the vehicle, a processing unit (20) for processing the image data, and a reproduction unit (30) for reproducing at least one first image section (410) and one second image section (420) of the area of view (40) captured by the capture unit (10). The processing unit provides different resolutions of image data depending on the position of the tractor with respect to the trailer.

A view system for a vehicle (1) with a tractor (2) and a trailer (3). The view system has a capture unit (10) with an image sensor (12) for capturing image data of an area of view, around the vehicle, a processing unit (20) for processing the image data, and a reproduction unit (30) for reproducing at least one first image section (410) and one second image section (420) of the area of view (40) captured by the capture unit (10). The processing unit provides different resolutions of image data depending on the position of the tractor with respect to the trailer.