An image acquisition method includes: exposing a pixel array to obtain a first color original image and a second color original image, data of the first color original image being generated by at least one color photosensitive pixel in a sub-unit, and data of the second color original image being generated by at least one transparent photosensitive pixel and the at least one color photosensitive pixel in the sub-unit; performing interpolation on the first color original image to obtain first interpolated images of multiple color channels, and performing interpolation on the second color original image to obtain a second interpolated image of at least one color channel; fusing the second interpolated image with the first interpolated images to obtain fused images of the multiple color channels; and acquiring a target image according to the fused image of the multiple color channels.

An image acquisition method, a camera assembly, and a mobile terminal are provided. The image acquisition method includes: acquiring a first color original image and a second color original image by exposing the pixel array, each piece of first color original image data in the first color original image being generated by at least one color photosensitive pixel in a sub-unit, and each piece of second color original image data in the second color original image being generated by at least one transparent photosensitive pixel and at least one color photosensitive pixel in the sub-unit; and fusing the first color original image and the second color original image to acquire a target image.

The present disclosure relates to an imaging apparatus, an imaging method, and a program that enable exposure control on a captured image in a non-Bayer pattern by an exposure control method designed for captured images in Bayer patterns.

When a Bayering process is performed on a captured image in an RGBW pixel array, a level correction unit corrects the signal level of the captured image so that an earlier level that is the signal level of each white pixel with the highest sensitivity in the captured image prior to the Bayering process becomes equal to a later level that is the signal level of each green pixel to be used in exposure control on an image in a Bayer pattern that is the RGB image after the Bayering process. The present disclosure can be applied to imaging apparatuses, for example.

Systems and methods for implementing array cameras configured to perform super-resolution processing to generate higher resolution super-resolved images using a plurality of captured images and lens stack arrays that can be utilized in array cameras are disclosed. An imaging device in accordance with one embodiment of the invention includes at least one imager array, and each imager in the array comprises a plurality of light sensing elements and a lens stack including at least one lens surface, where the lens stack is configured to form an image on the light sensing elements, control circuitry configured to capture images formed on the light sensing elements of each of the imagers, and a super-resolution processing module configured to generate at least one higher resolution super-resolved image using a plurality of the captured images.

An image sensor includes a pixel array with pixels arranged in a first direction and a second direction, intersecting the first direction. Each of the pixels includes a photodiode, a pixel circuit below the photodiode, and a color filter on or above the photodiode. A logic circuit acquires a pixel signal from the pixels through a plurality of column lines extending in the second direction. The pixels include color pixels and white pixels, the number of white pixels being greater than the number of color pixels. The pixel circuit includes a floating diffusion in which charges of the photodiode are accumulated and transistors outputting a voltage corresponding to amounts of charges in the floating diffusion. Each of the color pixels shares the floating diffusion with at least one neighboring white pixel, adjacent thereto in the second direction, among the white pixels.

An image sensor includes an array of multiple-photodiode cells, each photodiode coupled through a selection transistor to a floating diffusion of the cell, the selection transistors controlled by respective transfer lines, a reset, a sense source follower, and a read transistor coupled from the source follower to a data line. The array includes phase detection rows with phase detection cells and normal cells; and a compensation row of more cells. In embodiments, each phase detection row has cells with at least one photodiode coupled to the floating diffusion by selection transistors controlled by a transfer line separate from transfer lines of selection transistors of adjacent normal cells of the row. In embodiments, the compensation row has cells with photodiodes coupled to the floating diffusion by selection transistors controlled by a transfer line separate from transfer lines of selection transistors of adjacent normal cells of the compensation row.

An imaging device includes a pixel array of 1×3 pixel circuits that include 3 photodiodes in a column. Bitlines are coupled to the 1×3 pixel circuits. The bitlines are divided into groupings of 3 bitlines per column of the 1×3 pixel circuits. Each column of the 1×3 pixel circuits includes a plurality of first banks coupled to a first bitline, a plurality of second banks coupled to a second bitline, and a plurality of third banks coupled to a third bitline of a respective grouping of the 3 bitlines. The 1×3 pixel circuits are arranged into groupings of 3 1×3 pixel circuits per nine cell pixel structures that form a plurality of 3×3 pixel structures of the pixel array.

An imaging device includes a pixel array of 1×3 pixel circuits that include 3 photodiodes in a column. Bitlines are coupled to the 1×3 pixel circuits. The bitlines are divided into groupings of 3 bitlines per column of the 1×3 pixel circuits. Each column of the 1×3 pixel circuits includes a plurality of first banks coupled to a first bitline, a plurality of second banks coupled to a second bitline, and a plurality of third banks coupled to a third bitline of a respective grouping of the 3 bitlines. The 1×3 pixel circuits are arranged into groupings of 3 1×3 pixel circuits per nine cell pixel structures that form a plurality of 3×3 pixel structures of the pixel array.

[Object] To make it possible to improve reading efficiency of pixel signals in a signal processing device in which rows of pixels having different pixel arrays are arranged at intervals of one line.

[Solution] Provided is a signal processing device, including: a pixel array unit configured to include first pixels, second pixels, third pixels, and fourth pixels which have different spectral sensitivity characteristics and are arranged in a matrix form; and a pixel signal reading unit configured to read pixel signals obtained from the plurality of pixels arranged in the pixel array unit. The first pixels are adjacent to the second pixels in a row direction and a column direction, the second pixels are arranged at a two-pixel pitch in the row direction and the column direction, the third pixels are adjacent to the second pixels in one diagonal direction, the fourth pixels are adjacent to the second pixels in the other diagonal direction, and the pixel signal reading unit adds and reads the pixel signals obtained from the plurality of first pixels.

The present disclosure relates to an image pickup apparatus, an image pickup method, a program, and an image processing apparatus that enable a color image to be generated on the basis of an infrared image and a visible image captured using an image pickup device that uses a focal plane reading system.

An image pickup apparatus according to the present disclosure includes: an image pickup device that generates, in a one frame period, sub-frame images in a number corresponding to 3 or more sub-frame periods; an infrared light irradiation unit that turns on/off irradiation of infrared light onto an image pickup range in a time length unit that is the same as the sub-frame period in the one frame period; and a color image generation unit that generates a color image in a predetermined frame rate on the basis of an infrared image based on the sub-frame image in which a period during which the infrared light is irradiated is included in an exposure time and a visible image based on the sub-frame image in which the period during which the infrared light is irradiated is not included in the exposure time. The present disclosure is applicable to a surveillance camera, for example.