A computer-implemented method includes capturing, with a camera, a first image of a physical item at a first camera position, detecting borders associated with the physical item, based on the first image, generating an overlay that includes a plurality of objects that are positioned within one or more of the borders associated with the physical item, capturing, with the camera, subsequent images of the physical item, where each subsequent image is captured with a respective subsequent camera position, and during capture of the subsequent images, displaying an image preview that includes the overlay. The method further includes establishing correspondence between pixels of the first image and pixels of each of the subsequent images and generating a composite image of the physical item, where each pixel value of the composite image is based on corresponding pixel values of the first image and the subsequent images.

This disclosure provides systems, methods, and devices for image processing that supports high dynamic range (HDR) photography. In some aspects, a method of generating a full-resolution HDR photograph with in-sensor zoom includes receiving first and second image data corresponding to first and second exposure captures of a scene. First and second full-resolution image frames may be generated from the first and second image data, which are subsequently processed with HDR fusion to obtain an output image frame with higher dynamic range than either the first or second image data. The first full-resolution image frame may be determined from both the first and second image data by compensating the second image data for differences between the first and second exposures. Other aspects and features are also claimed and described.

An electronic device and a control method therefor are provided. The electronic device includes a main lens, an image sensor, and at least one processor. When an input for acquiring an image is received, the at least one processor is configured to acquire, from the at least one main lens, a first image including an object by setting the image sensor to a first position corresponding to a first focal point for the object, acquire, from the at least one main lens, a second image including the object by setting the image sensor to a second position corresponding to a second focal point for the object, and combine the acquired first image and the acquired second image to generate a combined image. The first focal point and the second focal point are positions symmetrical to each other with reference to an on-focus position for the object.

An electronic device and a method for generating a high dynamic range (HDR) image frame. The method includes obtaining at least two digital image frames, where each of the at least two digital image frames is captured with a different exposure setting. The method includes generating, by a processor, a radiance map from the at least two digital image frames, and performing image fusion of the at least two digital image frames to generate a fused image. Further, the method includes combining, by the processor, color values of image channels of the fused image and the radiance map to generate the HDR image frame.

An image processing apparatus, comprising a memory that stores first image data, and a processor that includes an image associated information processing section, wherein the image associated information processing section, for the image data of a single frame that has been taken at a plurality of shooting conditions, within the first image data that has been stored in the memory, acquires image region information, relating to an image region in which shooting is carried out at different shooting conditions, and image associated information of the image region, associates the image region information and the image associated information and subjects the first image data to image processing, and generates second image data.

An image capturing apparatus comprises a determination unit configured to determine an exposure in order to capture a visible light image and an invisible light image; an image capturing unit configured to capture a visible light image and a plurality of invisible light images with an exposure determined by the determination unit; a synthesis unit configured to synthesize the plurality of invisible light images and generate a synthetic invisible light image; and a correction unit configured to correct the visible light image using the synthetic invisible light image.

According to one embodiment, an image processing device includes an imaging element, a lens and an image processor. Light passes through the lens toward the imaging element. A relative position of the imaging element and the lens is changeable. The image processor acquires a first image and a second image. The image processor derives a first stored image by adding at least a portion of the second image to the first image. The first image is captured by the imaging element when the relative position is in a first range. The second image is captured by the imaging element when the relative position is in a second range different from the first range.

The present invention provides a technique of reducing colored afterimages. To solve this problem, an image capturing system includes the following structure: A color separation optical system disperses subject light into a plurality of wavelength ranges, and forms images of a plurality of color components. A plurality of image capturing elements capture the respective images of the plurality of color components, and generate the respective color components of a video signal. A color-specific exposure setting unit sets respective exposure periods for the plurality of color components. An exposure control unit performs exposure control α of approximately simultaneously exposure-controlling each of the plurality of image capturing elements to obtain a video signal (hereafter referred to as a reference video signal) in a common period shorter than or equal to a shortest period of the respective exposure periods set for the color components. The exposure control unit also performs exposure control β of exposure-controlling each of the plurality of image capturing elements to obtain a video signal (hereafter referred to as an extended video signal) in a period obtained by subtracting the common period from an exposure period of a corresponding color component.

Systems and methods for adjusting an exposure parameter of an imaging device are disclosed. A first exposure level of the imaging device is identified, and a first image of a scene is captured via the imaging device at the first exposure level. The first image of the scene comprises a plurality of polarization images corresponding to different degrees and angles of polarization. Each of the polarization images comprise a plurality of color channels. A gradient for the first image is computed based on the plurality of the polarization images, and a second exposure level is computed based on the gradient. A second image of the scene is captured based on the second exposure level, where the gradient of the second image is greater than a gradient for the first image.

Systems and methods for adjusting an exposure parameter of an imaging device are disclosed. A first exposure level of the imaging device is identified, and a first image of a scene is captured via the imaging device at the first exposure level. The first image of the scene comprises a plurality of polarization images corresponding to different degrees and angles of polarization. Each of the polarization images comprise a plurality of color channels. A gradient for the first image is computed based on the plurality of the polarization images, and a second exposure level is computed based on the gradient. A second image of the scene is captured based on the second exposure level, where the gradient of the second image is greater than a gradient for the first image.