An image processing system is disclosed, comprising: an M-lens camera, a compensation device and a correspondence generator. The M-lens camera generates M lens images. The compensation device generates a projection image according to a first vertex list and the M lens images. The correspondence generator is configured to conduct calibration for vertices to define vertex mappings, horizontally and vertically scan each lens image to determine texture coordinates of its image center, determine texture coordinates of control points according to the vertex mappings, and P1 control points in each overlap region in the projection image; and, determine two adjacent control points and a coefficient blending weight for each vertex in each lens image according to the texture coordinates of the control points and the image center in each lens image to generate the first vertex list, where M>=2.

A method for processing images by an information handling system includes receiving image data including first frames captured using a first exposure at a first frame rate and second frames captured using a second exposure at a second frame rate. The first frame rate is greater than the second frame rate. The method includes merging each second frame of the second frames with each first frame of a corresponding plurality of the first frames to generate a corresponding plurality of merged frames. Each merged frame of the corresponding plurality of merged frames may have a dynamic range of tonal values greater than each dynamic range of tonal values of each frame merged to form the merged frame.

The invention provides an image processing apparatus which comprises a controller which causes an image sensing device to execute either a first mode in which outputs image data of a first resolution, or a second mode in which outputs image data of a second resolution lower than the first resolution; and an evaluating circuit which, by outputting image data of the second resolution in relation to acquired image data, obtains an index value that relates to a spatial frequency of a frequency band in which a signal level decreases in image data of the second resolution more than in image data of the first resolution, wherein the evaluating circuit detects, by machine learning, the index value of image data of the second resolution, and the controller, based on the detected index value, selects either the first or second mode.

A camera array, an imaging device and/or a method for capturing image that employ a plurality of imagers fabricated on a substrate is provided. Each imager includes a plurality of pixels. The plurality of imagers include a first imager having a first imaging characteristics and a second imager having a second imaging characteristics. The images generated by the plurality of imagers are processed to obtain an enhanced image compared to images captured by the imagers. Each imager may be associated with an optical element fabricated using a wafer level optics (WLO) technology.

An image-capturing device includes: a photographic optical system; a photoelectric conversion element array made up with a plurality of photoelectric conversion elements arrayed therein; a micro-lens array made up with a plurality of micro-lenses arrayed therein; a data creation unit that creates pixel data at a plurality of pixels on a specific image forming plane by applying filter matrix data to output signals provided from the plurality of photoelectric conversion elements; and an image synthesis unit that synthetically generates an image on the specific image forming plane at a given position assumed along an optical axis of the photographic optical system, based upon the pixel data. The filter matrix data assume a two-dimensional data array pattern conforming to a specific intensity distribution with a distribution center thereof set at an element corresponding to a central position of a projection image of each of the plurality of pixels.

Provided are an image composition apparatus for composing color images with black-and-white images including infrared components, and an image composition method thereof The image composition method includes generating a first image signal with color information and a second image signal including infrared components without color information, dividing the first image signal into a brightness signal and a color signal, composing the brightness signal of the first image signal with a brightness signal of the second image signal to generate a composed brightness signal, and composing the composed brightness signal with the color signal of the first image signal to generate a color image.

Systems and methods for high dynamic range imaging using array cameras in accordance with embodiments of the invention are disclosed. In one embodiment of the invention, a method of generating a high dynamic range image using an array camera includes defining at least two subsets of active cameras, determining image capture settings for each subset of active cameras, where the image capture settings include at least two exposure settings, configuring the active cameras using the determined image capture settings for each subset, capturing image data using the active cameras, synthesizing an image for each of the at least two subset of active cameras using the captured image data, and generating a high dynamic range image using the synthesized images.

An image pickup device which captures sound and a moving image prevents deterioration in a reproduction quality. A scene change detector detects a frame at the time of a scene change from among a plurality of frames imaged at a predetermined frame rate as a detection frame. A frame rate converting unit converts a frame rate of the frame imaged outside a detection to a lower frame rate. A video reproduction time setting unit sets a reproduction time when reproduction is performed at the lower frame rate as a video reproduction time. An audio reproduction time setting unit sets an audio reproduction time at constant intervals for sounds recorded at constant intervals outside the detection period and sets an audio reproduction time in synchronization with the video reproduction time corresponding to the detection frame relative to sound recorded in the detection period.

An image processing apparatus (image processing circuit 125) includes a determiner (125a) that determines a weight coefficient which varies depending on a position in each of a plurality of parallax images and an image generator (125b) that synthesizes the plurality of parallax images based on the weight coefficient to generate an image.

Various methods and systems are provided for image processing for multiple cameras. In one embodiment, a method comprises acquiring image frames with a plurality of image frame sources configured with different acquisition settings, processing the image frames based on the different acquisition settings to generate at least one final image frame, and outputting the at least one final image frame. In this way, information from different image frame sources such as cameras may be leveraged to achieve increased frame rates with improved image quality and a desired motion appearance.