To acquire a correction image by performing a sub-pixel shift process for shifting an image using a pixel interpolation filter by a pixel shift amount between pixels and a frequency correction process for correcting a frequency characteristic of the image after shifted.

An image processing apparatus includes processing circuitry. The processing circuitry is configured to detect a positional shift amount of each of a plurality of images; select a composite target image from the plurality of images based on the detected positional shift amount; and obtain a composite image based on the positional shift amount and the selected composite target image.

An image capturing apparatus comprises: an image capturing unit configured to capture a plurality of RAW image data sets while shifting a position of an image sensor relative to an optical axis; a difference generation unit configured to generate difference data; an encoding unit configured to encode the difference data; and a recording unit configured to record the encoded difference data, wherein, when generating difference data regarding a first RAW image data set and a second RAW image data set included in the plurality of RAW image data sets, the difference generation unit shifts the first RAW image data set, and obtains a difference between pieces of pixel data having the same color component, respectively included in the first RAW image data set and the second RAW image data set, to generate the difference data.

The present disclosure relates to devices and methods for acquiring an image having two-dimensional spatial resolution and spectral resolution. An example method comprises: acquiring a frame using rows of photo-sensitive areas on a sensor surface detecting incident light from an object imaged by an optical system onto an image plane, wherein rows of photo-sensitive areas are arranged to receive different wavelengths; moving the sensor surface in a direction perpendicular to a longitudinal direction of the rows; repeating the acquiring and moving for acquiring a plurality of frames recording different spectral information for respective positions on the object; and combining information from the plurality of frames to form multiple channels of an image, wherein each channel is formed based on detected light in respective rows and represent a two-dimensional image of the object for a different wavelength.

The present disclosure relates to a solid-state imaging apparatus that can further downsize the size of the apparatus. The solid-state imaging apparatus is configured by laminating a first structure body, at which a pixel array unit in which pixels for performing photoelectric conversion are two-dimensionally aligned is formed, and a second structure body, at which an output circuit unit for outputting a pixel signal outputted from the pixels to the outside of the apparatus is formed. The output circuit unit, a through via which penetrates a semiconductor substrate constituting a part of the second structure body, and a signal output external terminal connected to the outside of the apparatus are arranged under the pixel array unit of the first structure body, the output circuit unit is connected to the signal output external terminal via the through via, and the outermost surface of the apparatus is a resin layer formed on an upper layer of an on-chip lens of the pixel array unit. The present technology can be applied to, for example, solid-state imaging apparatuses and the like incorporated into wearable products and the like.

The present disclosure provides a method and a device for compositing a plurality of images. The method includes obtaining a first exposure time t required for current photographing. The first exposure time t is divided into N segments where N is M power of 4, and M is a positive integer. A micro-electro-mechanical system (MEMS) controls an image sensor to move clockwise or anticlockwise according to a step length of a preset number of pixels. The image sensor is controlled to expose for a second exposure time t/N after each movement of the image sensor according to the preset number of pixels, to obtain N images. The N images are composited to obtain a composite picture.

Systems and methods are disclosed for generating hyperspectral images, which may correspond to a three dimensional image in which two dimensions correspond to a spatial field of view and a third dimension corresponds to a frequency domain absorption spectrum. Disclosed systems and methods include those employing dual optical frequency comb Fourier transform spectroscopy and computational imaging for generation of hyperspectral images. Such a combination advantageously allows for imaging systems to exhibit low size, weight, and power, enabling small or handheld sized imaging devices.

An radiation imaging system acquires a plurality of radiation images by radiation imaging with a plurality of energies, and detects, based on pixel values of the plurality of radiation images, whether there is any abnormal pixel in at least one of the plurality of radiation images.

An imaging device for capturing an image of a scene, comprising: an image sensor; an optical arrangement operable to focus light from a portion of the scene onto the image sensor whilst preventing light from other portions of the scene from being focused onto the sensor; a controller configured to cause the optical arrangement to focus light from a sequence of portions of the scene onto the sensor so that the sensor captures the said sequence of portions of the scene; and a processor configured to use the captured portions of the scene to construct an image of the scene.

An image acquisition apparatus includes a color filter on which a plurality of types of color filter elements are arranged, an optical path modulation optical element configured to shift an incident position of an image on the color filter by electrically modulating an optical path of the image, and a photoelectric conversion cell array configured to acquire image information for each color by detecting, in pixel units, light which has passed through the color filter. A color image is obtained by acquiring, in a time division manner, the image information for each color of the image of which a position is changed by the optical path modulation optical element by using a detection signal of the photoelectric conversion cell array, and combining the acquired image information for each color.