An electronic control unit provided in a vehicle is provided. The electronic control unit comprises a communication unit for receiving information on vehicle electronic devices from one or more vehicle electronic devices provided in the vehicle, and a processor for selecting the information on vehicle electronic devices from any one of the vehicle electronic devices in response to occurrence of an event and controlling the communication unit to first transmit the selected information to a server.

An electronic control unit provided in a vehicle is provided. The electronic control unit comprises a communication unit for receiving information on vehicle electronic devices from one or more vehicle electronic devices provided in the vehicle, and a processor for selecting the information on vehicle electronic devices from any one of the vehicle electronic devices in response to occurrence of an event and controlling the communication unit to first transmit the selected information to a server.

The present invention provides an image shooting method and an electronic device. The image shooting method includes: receiving a first input; in response to the first input, obtaining a first video stream and a second video stream with a same shot content acquired by a camera module; extracting a target object in the shot content of the first video stream to obtain a first intermediate video stream of the target object; removing the target object in the shot content of the second video stream and performing image registration compensation on areas at which the target object is located, to obtain a second intermediate video stream; and generating, based on the first intermediate video stream and the second intermediate video stream, a target video; where the first intermediate video stream and the second intermediate video stream are different in frame rate.

This information processing apparatus includes an image processing unit that detects a position of a light source in image data captured by an imaging apparatus and estimates an unnecessary light generation position in the image data on the basis of the detected position of the light source. The image processing unit detects, with respect to a plurality of pieces of image data respectively captured by a plurality of imaging apparatuses having partially common fields of view, positions of light sources and estimates unnecessary light generation positions on the basis of the detected positions of the light sources and combines pieces of image data of common field-of-view portions respectively captured by the plurality of imaging apparatuses and generates image data of the unnecessary light generation position with unnecessary light removed or reduced.

An image processing device performs a combining process of disposing a second image in a first image captured by a first imaging device, the second image being an image of the imaging field of view of a second imaging device capable of imaging a partial field of view in the imaging field of view of the first imaging device.

An imaging device is presented for use in an imaging system capable of improving the image quality. The imaging device has one or more optical systems defining an effective aperture of the imaging device. The imaging device comprises a lens system having an algebraic representation matrix of a diagonalized form defining a first Condition Number, and a phase encoder utility adapted to effect a second Condition Number of an algebraic representation matrix of the imaging device, smaller than said first Condition Number of the lens system.

An imaging device is presented for use in an imaging system capable of improving the image quality. The imaging device has one or more optical systems defining an effective aperture of the imaging device. The imaging device comprises a lens system having an algebraic representation matrix of a diagonalized form defining a first Condition Number, and a phase encoder utility adapted to effect a second Condition Number of an algebraic representation matrix of the imaging device, smaller than said first Condition Number of the lens system.

This application discloses a photographing method and apparatus, to overcome blurring that occurs during photographing. When a zoom ratio is greater than a first zoom ratio threshold, a long-focus camera is started to capture an image. A zoom ratio of the long-focus camera is greater than or equal to the first zoom ratio threshold. Because a high zoom ratio causes large shake, a rotational blur occurs in the image. According to the photographing method disclosed in this application, a first neural network model for rotational image deblurring is used to implement rotational image deblurring processing. In this way, high imaging quality of an image, a video, or a preview image is presented to a user to some extent, and the imaging effect may not be inferior to the effect of photographing with a tripod.

This application discloses an image processing method and apparatus, and relates to the field of image processing technologies, to help optimize a color, a contrast, or a dynamic range of an image, so that an optimized image can be more objective, and robustness is improved. The method is applied to a terminal including a first camera and a second camera. The method includes: when an ISO of the first camera in a current photographing environment is greater than a first threshold, capturing a first image for a first scenario in the current photographing environment; capturing a second image for the first scenario; and optimizing the first image based on the second image to obtain a third image. An image style of the second image is better than that of the first image.

An electronic apparatus includes: an image sensor for acquiring an image including normal pixel values that are sensed during a first exposure time and short exposure pixel values that are sensed during a second exposure time that is shorter than the first exposure time; and a processor configured to acquire flag information that indicates that a selected region, among a plurality of regions of the image, is one of a motion region and a normal region by using an exposure ratio of the first exposure time and the second exposure time and by using a short exposure pixel value and normal pixel values, which are included in the selected region, and configured to output a restoration image including a restoration pixel value that is corrected from the short exposure pixel value that is included in the selected region, based on the flag information.